CN211999114U - Double-core water purification system and double-core water purifier - Google Patents

Abstract

The present disclosure relates to a dual-core water purification system and a dual-core water purifier. The double-core water purification system comprises a composite filter element, a preposed filtering passage, a reverse osmosis filter element, a reverse osmosis filtering passage, a purified water outlet and a control device; the composite filter element comprises a front filter assembly, a first water inlet and a first water outlet of the front filter assembly; the reverse osmosis filter element is provided with a second water inlet and a second water outlet; the prepositive filtering passage comprises a water inlet electromagnetic valve and a booster pump; the reverse osmosis filtering passage comprises a water storage bag, a water pump and a pressure testing device which are communicated; the control device is used for acquiring the pressure value detected by the pressure testing device, and when the pressure value meets the preset condition, the water inlet electromagnetic valve is indicated, and the booster pump and the water suction pump are simultaneously opened. The technical scheme improves the water flow speed of the purified water outlet; meanwhile, the cost of the whole double-core water purification system is reduced, the popularization and the use of the water purifier are facilitated, the volume of the whole double-core water purification system is reduced, and the condition that too much space is occupied under a kitchen is avoided.

Description

Double-core water purification system and double-core water purifier

Technical Field

The utility model relates to a water purification technical field especially relates to a two-core water purification system and two-core water purifier.

Background

In order to improve the quality of drinking water, more and more households are equipped with water purifiers through which tap water or water directly supplied from a water source is treated into purified water for use.

In the related art, water purifiers for household use are generally small-flux water purifiers, i.e., 50-gallon, 75-gallon or 100-gallon water purifiers, corresponding to water discharge amounts of 0.13L/min, 0.19L/min or 0.26L/min, respectively. Since the water yield of the small-flux water purifier is small, it is necessary to prepare purified water in advance and store the prepared purified water in a pressure tank. When the user got the water like this, the water purifier can follow and acquire water purification and output in this overhead tank, and this moment this water purifier can have great play water speed, and the user of being convenient for takes.

However, the pressure tank has a large volume and occupies a space under a kitchen, so that the space under the kitchen is easily crowded.

Disclosure of Invention

In order to overcome the problems in the related art, the embodiment of the disclosure provides a dual-core water purification system and a dual-core water purifier. The technical scheme is as follows:

according to a first aspect of embodiments of the present disclosure, there is provided a dual-cartridge water purification system comprising a composite filter element, a pre-filtration passage, a reverse osmosis filter element, a reverse osmosis filtration passage, a purified water outlet and a control device; the composite filter element comprises a front filter assembly, a first water inlet and a first water outlet of the front filter assembly; the reverse osmosis filter element is provided with a second water inlet and a second water outlet;

the first water inlet is connected with an external water source;

the first water outlet is communicated with a second water inlet of the reverse osmosis filter element through the pre-filtering passage;

the second water outlet of the reverse osmosis filter element is communicated with the purified water outlet through the reverse osmosis filtering passage;

the pre-filtering passage comprises a water inlet electromagnetic valve and a booster pump which are communicated, and the water inlet electromagnetic valve and the booster pump are both connected with the control device;

the reverse osmosis filtering passage comprises a water storage bag, a water suction pump and a pressure testing device which are communicated, and the pressure testing device and the water suction pump are both connected with the control device; the water storage bag stores first purified water which is filtered by the pre-filtering component and the reverse osmosis filter element in advance;

the pressure testing device is used for detecting the pressure value of the reverse osmosis filtering passage;

the control device is used for obtaining the pressure value, and when the pressure value satisfies the preset condition, instruct the water inlet solenoid valve, the booster pump with the suction pump is opened simultaneously, makes the first water purification of water storage bag storage with pass through composite filter element with the second water purification after the reverse osmosis filter element filters flows to simultaneously the water purification export.

The technical scheme provided by the embodiment of the disclosure can have the following beneficial effects: when the pressure value is detected to be reduced, the water inlet electromagnetic valve, the booster pump and the water suction pump of the double-core water purification system can be simultaneously opened, so that first purified water stored in the water storage bag in advance and second purified water filtered by the composite filter element and the reverse osmosis filter element simultaneously flow to the purified water outlet, and the water flow speed of the purified water outlet is improved; meanwhile, the water storage bag is used for storing purified water, the cost of the whole double-core water purification system is reduced, the popularization and the use of the water purifier are facilitated, and the volume of the water storage bag for storing purified water is small, so that the volume of the whole double-core water purification system is reduced, and the condition that too much space is occupied under a kitchen is avoided.

In one embodiment, the reverse osmosis filtration circuit further comprises a bypass circuit;

one end of the branch passage is communicated with the second water outlet, and the other end of the branch passage is communicated with the purified water outlet.

In one embodiment, the dual cartridge water purification system further comprises a post-filtration pathway; the composite filter element comprises a post-filter assembly and a third water inlet and a third water outlet of the post-filter assembly;

the second water outlet is communicated with the third water inlet through the reverse osmosis filtering passage;

the third water outlet is communicated with the purified water outlet through the rear filtering passage.

In one embodiment, the dual core water purification system further comprises a waste water passageway and a waste water outlet; the reverse osmosis filter element is provided with a wastewater outlet;

the waste water outlet is connected with the waste water passage and is used for leading the waste water generated by the reverse osmosis filter element to flow to the waste water outlet through the waste water passage.

In one embodiment, the waste water pathway includes a waste water solenoid valve in a normally closed state connected to the control device; the reverse osmosis filtering passage also comprises a check valve, and the check valve is arranged between the reverse osmosis filter element and the pressure testing device;

the control device is used for indicating the wastewater electromagnetic valve to be opened when the reverse osmosis filter element is cleaned, so that wastewater generated when the reverse osmosis filter element is flushed flows to the wastewater outlet through the wastewater passage;

the check valve is used for maintaining the pressure of the reverse osmosis filtering passage when the wastewater electromagnetic valve is opened.

In one embodiment, the reservoir bag is made of thermoplastic polyurethane elastomer rubber TPU.

In one embodiment, the reservoir bag has a volume of 3 litres.

In one embodiment, the pressure testing device comprises a high-voltage switch.

In one embodiment, the pre-filter assembly comprises a polypropylene fiber PP and a carbon rod composite filter element; the post-filter assembly includes an activated carbon filter element.

According to a second aspect of the embodiments of the present disclosure, there is provided a dual-core water purifier, comprising the dual-core water purification system of any one of the embodiments of the first aspect.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the present disclosure and together with the description, serve to explain the principles of the disclosure.

Fig. 1 is a schematic structural view illustrating a dual-cartridge water purification system according to an exemplary embodiment.

Fig. 2 is a schematic structural view of a dual-cartridge water purification system according to an exemplary embodiment.

Fig. 3 is a schematic diagram illustrating a dual-cartridge water purification system according to an exemplary embodiment.

Detailed Description

Reference will now be made in detail to the exemplary embodiments, examples of which are illustrated in the accompanying drawings. When the following description refers to the accompanying drawings, like numbers in different drawings represent the same or similar elements unless otherwise indicated. The implementations described in the exemplary embodiments below are not intended to represent all implementations consistent with the present disclosure. Rather, they are merely examples of apparatus and methods consistent with certain aspects of the present disclosure, as detailed in the appended claims.

The embodiment of the present disclosure provides a dual-core water purification system 10, as shown in fig. 1, the dual-core water purification system 10 includes a composite filter element 101, a pre-filtration passage 102, a reverse osmosis filter element 103, a reverse osmosis filtration passage 104, a purified water outlet 105 and a control device (not shown in fig. 1). Composite cartridge 101 comprises a pre-filter assembly (not shown in fig. 1) having a first water inlet 10a and a first water outlet 10 b. The reverse osmosis cartridge 103 is provided with a second water inlet 10c and a second water outlet 10 d.

Wherein the first water inlet 10a is connected to an external water source. The first water outlet 10b communicates with the second water inlet 10c of the reverse osmosis cartridge 103 through the pre-filtration passage 102. The second water outlet 10d of the reverse osmosis filter element 103 is communicated with the clean water outlet 105 through the reverse osmosis filtering passage 104. The pre-filter passage 102 comprises a water inlet electromagnetic valve 1021 and a booster pump 1022 which are communicated, and the water inlet electromagnetic valve 1021 and the booster pump 1022 are both connected with a control device. The reverse osmosis filtering passage 104 comprises a water storage bag 1041, a water suction pump 1042 and a pressure testing device 1043 which are communicated with each other, the pressure testing device 1043 and the water suction pump 1042 are both connected with the control device, and the water storage bag 1041 stores first purified water which is filtered by the front filtering component and the reverse osmosis filter element 103 in advance.

The pressure test device 1043 is used for detecting the pressure value of the reverse osmosis filtering passage 104. The control device is used for acquiring a pressure value, and when the pressure value meets a preset condition, the water inlet electromagnetic valve 1021 is indicated, and the booster pump 1022 and the water pump 1042 are simultaneously opened, so that the first purified water stored in the water storage bag 1041 and the second purified water filtered by the composite filter element 101 and the reverse osmosis filter element 103 simultaneously flow to the purified water outlet 105.

For example, the water source may be tap water provided by a municipal administration, or may be well water or river water, which is not limited in the embodiments of the present disclosure. After the first water inlet 10a is connected to the water source, the control device may detect whether the water storage bag 1041 stores the first purified water. If not, the control device may instruct the water inlet solenoid valve 1021 and the booster pump 1022 to be turned on, at this time, the water flow of the water source enters the pre-filter assembly of the composite filter element 101 through the first water inlet 10a, enters the pre-filter passage 102 from the first water outlet 10b after being filtered by the pre-filter assembly, then is pressurized by the booster pump 1022 (because the reverse osmosis filter element requires a water flow pressure of more than 0.7kg (kilogram), the water flow needs to be pressurized by the booster pump 1022), flows into the reverse osmosis filter element from the second water inlet 10c, and flows into the water storage bag 1041 from the second water outlet 10d after being filtered by the reverse osmosis filter element to be stored, because the water pump 1042 is not turned on at this time, the first purified water may completely flow into the water storage bag 1041, and does not flow to the purified water outlet 105 through the reverse osmosis filter.

If the first purified water is stored in the water storage bag 1041, the control device may obtain the pressure value of the reverse osmosis filtration path 104 detected by the pressure testing device 1043 in real time. Specifically, when the user needs water, the user can take water from the purified water outlet 105, and the purified water outlet 105 can be provided with a faucet. When the user takes water, the water pressure of the reverse osmosis filtration path 104 is lowered, that is, the pressure value detected by the pressure test device 1043 is lowered. The control means may determine in real time whether the pressure value is less than or equal to a preset threshold value. If not, it indicates that the user does not take water, and the dual-core water purification system 10 can keep the current state. If yes, it indicates that the user is getting water, at this time, the control device may instruct the water inlet solenoid valve 1021, the booster pump 1022 and the water pump 1042 to be simultaneously opened, the water pump 1042 pumps the first purified water stored in the water storage bag 1041, and at the same time, the water inlet solenoid valve 1021, and after the booster pump 1022 is opened, the pre-filter assembly and the reverse osmosis filter element 103 in the composite filter element 101 start to make water, that is, the second purified water obtained by filtering through the pre-filter assembly and the reverse osmosis filter element 103 while pumping the first purified water may also flow to the purified water outlet 105 through the reverse osmosis filter passage 104, that is, the water obtained by the user at the purified water outlet 105 is a mixed water of the first purified water and the second purified water, so as to avoid a problem of a high TDS (Total dissolved solids) value of the first cup of water caused by long-term non-water taking; meanwhile, since the water pump 1042 and the pre-filter assembly and the reverse osmosis filter element 103 in the composite filter element 101 work simultaneously, the water flow at the purified water outlet 105 is relatively large, for example, if the water production speed of the dual-core water purification system 10 is about 0.5L/min (liter/min), the volume of the water storage bag 1041 is 3 liters, and the water pumping speed of the water pump 1042 is 1.5L/min, then when a user takes water, the water purification system can continuously output about 4L of water within 2 minutes at a speed of 2.0L/min, which can satisfy most water usage scenarios, and the user experience is better.

Alternatively, the reservoir bag 1041 may be made of TPU (Thermoplastic polyurethane elastomers). Preferably, the reservoir bag 1041 has a volume of 3 liters.

In the technical scheme provided by the embodiment of the present disclosure, when the pressure value is detected to be decreased, the water inlet solenoid valve 1021, the booster pump 1022 and the water pump 1042 of the dual-core water purification system 10 may be simultaneously opened, so that the first purified water pre-stored in the water storage bag 1041 and the second purified water filtered by the composite filter element 101 and the reverse osmosis filter element 103 simultaneously flow to the purified water outlet 105, thereby increasing the water flow rate of the purified water outlet 105; meanwhile, the water storage bag 1041 is used for storing purified water, the cost of the whole double-core water purification system is reduced, the popularization and the use of the water purifier are facilitated, and the volume of the water storage bag 1041 for storing purified water is small, so that the volume of the whole double-core water purification system is reduced, and the condition that too much space is occupied under a kitchen is avoided.

In one embodiment, as shown in fig. 2, the reverse osmosis filtration circuit 104 further comprises a bypass 1044. One end of the branch passage 1044 is communicated with the second water outlet 10d, and the other end is communicated with the purified water outlet 105.

For example, if the first purified water stored in the water storage bag 1041 and the second purified water filtered by the pre-filter assembly and the reverse osmosis filter element 103 need to be pumped by the water pump 1042, the pumping force of the water pump 1042 needs to be larger, and the price of the water pump 1042 is higher when the pumping force is larger, so that it is difficult to reduce the hardware cost of the whole dual-core water purification system 10 by using the water pump 1042 with large pumping force. In the embodiment of the present disclosure, a branch passage 1044 is disposed in the reverse osmosis filtration passage 104, one end of the branch passage 1044 is communicated with the second water outlet 10d of the reverse osmosis filter element 103, and the other end is communicated with the purified water outlet 105, that is, the second purified water sequentially filtered by the pre-filtration assembly of the composite filter element 101 and the reverse osmosis filter element 103 does not need to be pumped by the water pump 1042, and can directly flow from the second water outlet 10d to the purified water outlet 105 through the branch passage 1044. Because the water pump 1042 only needs to pump the first purified water stored in the water storage bag 1041, and the requirement on the pumping capacity is not high, the double-core water purification system 10 can select a low-value water pump with a small pumping capacity, so that the hardware cost of the whole double-core water purification system is reduced, and the popularization and the use of the water purification system are facilitated.

In one embodiment, as shown in fig. 3, the dual cartridge water purification system 10 further includes a post-filtration passage 106; the composite filter element 101 comprises a post-filter assembly and a third water inlet 10e and a third water outlet 10f of the post-filter assembly.

Wherein the second water outlet 10d is communicated with the third water inlet 10e through the reverse osmosis filtration path 104. The third water outlet 10f is communicated with the purified water outlet 105 through a post-filter passage 106.

For example, the water filtered by the pre-filter assembly and the reverse osmosis filter element may flow into the post-filter assembly of the composite filter element 101 again through the third water inlet 10e, and then flow to the purified water outlet 105 through the post-filter passage 106 after being filtered by the post-filter assembly.

Specifically, the user can take water from the purified water outlet 105 when the user needs the water. When the user takes water, the water pressure of the reverse osmosis filtration path 104 is lowered, that is, the pressure value detected by the pressure test device 1043 is lowered. The control means may determine in real time whether the pressure value is less than or equal to a preset threshold value. If not, it indicates that the user does not take water, and the dual-core water purification system 10 can keep the current state. If yes, it indicates that the user is getting water, at this time, the control device may instruct the water inlet solenoid valve 1021, the booster pump 1022 and the water pump 1042 to be simultaneously turned on, the water pump 1042 pumps the first purified water stored in the water storage bag 1041, the water inlet solenoid valve 1021, and after the booster pump 1022 is turned on, the composite filter element 101 and the reverse osmosis filter element also start to operate, that is, the water sequentially filtered by the pre-filter element and the reverse osmosis filter element 103 of the composite filter element 101 while pumping the first purified water may also enter the reverse osmosis filter path 104, flows into the post-filter element of the composite filter element 101 from the third water inlet 10e after being mixed in the reverse osmosis filter path 104, and flows to the purified water outlet 105 through the post-filter path 106 after being filtered by the post-filter element, that at this time, the water flowing out from the purified water outlet 105 is the water filtered by the post-filter element of the first purified water stored in the water storage bag 1041, and sequentially, The reverse osmosis filter element 103 and the second purified water obtained by filtering by the post-positioned filtering component of the composite filter element 101 are mixed. If the pressure value obtained by the control device returns to normal again, it indicates that the user has finished taking water, and at this time, the control device may instruct the water inlet solenoid valve 1021, the booster pump 1022 and the water pump 1042 to turn off.

As can be seen from the above description, firstly, the water obtained by the purified water outlet 105 is mixed water, so that the TDS value of the first cup of water flowing out from the purified water outlet 105 when the water is not used for a long time is reduced; secondly, since the water pump 1042 and the two filter elements work simultaneously, the water flow at the purified water outlet 105 is relatively large, for example, if the water production speed of the dual-core water purification system 10 is about 0.5L/min, the volume of the water storage bag 1041 is 3 liters, and the water pumping speed of the water pump 1042 is 1.5L/min, then when a user takes water, the water purification system can continuously output 4L of water at a speed of 2.0L/min within 2 minutes, which can meet most water usage scenarios, and user experience is better; thirdly, because the double-core water purification system 10 can reach the water outlet speed with large flux on the basis of small flux, a power adapter, a booster pump, a filter element and the like with small volume can be selected, namely the water outlet with large flux is realized at an economical and applicable price, and the cost of the whole double-core water purification system 10 is further reduced. Fourthly, the manufacturing cost of the water storage bag is far less than that of the pressure tank, so that the hardware cost of the whole double-core water purification system is reduced by adopting the water storage bag to store the first purified water, and the popularization and the use of the water purification system are facilitated; fifthly, the water storage bag in the double-core water purification system has small volume and small water storage capacity, so that the water can be stored quickly and is not easy to breed bacteria; sixth, since the reservoir bag 1041 does not require compressed air as compared to the pressure tank, a large amount of storage is achieved with a small amount, for example, a spatial pressure tank with a capacity of 3L, only 1.5L of water can be stored due to the compressed air, and a reservoir bag with a capacity of 3L can store up to 3L of water, thereby improving space utilization; seventh, the water storage bag can be arranged inside the water purifier, and an additional water storage pressure tank or water storage bag does not need to be arranged outside the main machine of the water purifier, so that the volume of the water purifier is reduced; eighth, if the water production speed of the dual-core water purification system 10 is about 0.5L/Min and the capacity of the water storage bag 1041 is 3L, the dual-core water purification system 10 can produce the water storage bag in about 6 minutes, and the conventional small-flux water purifier generally needs about 10 to 15Min to produce the water storage bag arranged outside the water storage bag, so that the interval time for continuously using the dual-core water purification system 10 is shortened, and the utilization rate of the dual-core water purification system 10 is improved.

Optionally, the pre-filter assembly may be a PP and carbon rod composite filter element, and may also be referred to as a PCB composite filter element; wherein the PP is a synthetic chemical fiber made of polypropylene fiber. This PCB composite filter core can filter the large granule impurity and some coloured impurity of aquatic, avoids the impurity damage of aquatic to intake original papers such as solenoid valve 1021, booster pump 1022 and reverse osmosis filter core to effectively improve this water purification system's life. The post-filter assembly can be an activated carbon filter element which is arranged at the final position of the purified water passage and is used for further filtering the flowing purified water, and metal ions for increasing the mouthfeel, such as ferrous ions or magnesium ions and the like, are added. In practical application, other filter elements can be replaced according to specific situations, and the embodiment of the disclosure does not limit the filter elements.

Optionally, the pressure testing device 1043 may be a high-voltage switch, and when it is detected that the pressure value is smaller than or equal to the preset threshold, a signal is sent to the control device, so that the control device can instruct the water inlet solenoid valve 1021, the booster pump 1022, and the water pump 1042 to be turned on simultaneously.

In the present disclosure, when a user takes water, the pressure in the reverse osmosis filtering path 104 decreases, the high-voltage switch closes the conductive loop, and the control device finds that the conductive loop is closed, and then controls the water inlet solenoid valve 1021, the booster pump 1022 and the water pump 1042 to open simultaneously, that is, to start pumping water and producing water simultaneously, so that the first purified water and the second purified water flow to the purified water outlet 105 simultaneously. When the user stops taking water, the pressure in the reverse osmosis filtering passage 104 returns to a larger state, the high-voltage switch disconnects the conductive loop, and the control device detects that the conductive loop is disconnected, and then controls the water inlet electromagnetic valve 1021, the booster pump 1022 and the water suction pump 1042 to be closed, so as to stop pumping water and producing water.

In one embodiment, referring to fig. 1, 2 and 3, the dual core water purification system 10 further comprises a waste water passageway 107 and a waste water outlet 108; the reverse osmosis filter element 103 is provided with a waste water outlet 10 g. The waste water outlet 10g is connected to a waste water passage 107 for flowing waste water generated by the reverse osmosis filter element 103 to a waste water outlet 108 through the waste water passage 107.

Illustratively, wastewater is produced when water is produced by the reverse osmosis cartridge 103. Meanwhile, in order to ensure the filtering effect, the dual-core water purification system 10 also needs to periodically flush the reverse osmosis filter element 103, and waste water is also generated during flushing. In order to facilitate the rapid discharge of the two types of wastewater, a wastewater passage 107 may be provided, the wastewater passage 107 is connected to the wastewater outlet 10g of the reverse osmosis filter element 103, a wastewater solenoid valve 1071 connected to the control device and in a normally closed state is provided, and a water through hole is provided on the wastewater solenoid valve 1071. When the waste water solenoid valve 1071 is closed, the diameter of the water passing through hole is smaller; when the waste water solenoid valve 1071 is opened, the diameter of the water passing hole is large. In practical application, the specific size of the water through hole can be selected according to the water purification capacity of the reverse osmosis filter element 103, that is, the higher the water purification capacity of the reverse osmosis filter element is, the smaller the aperture of the water through hole when the waste water solenoid valve 1071 is closed is.

Normally, the waste water solenoid valve 1071 is normally closed, and waste water produced by normal water production in the reverse osmosis filter element 103 flows into the waste water passage 107 through the waste water outlet 10g, and then flows to the waste water outlet 108 through the water passing hole having a small diameter. Meanwhile, the diameter of the water through hole is small, so that the pressurizing effect of the pressurizing pump 1022 is not affected. When the control device determines that the reverse osmosis filter element 103 needs to be flushed, the wastewater solenoid valve 1071 is indicated to be opened, the water inlet solenoid valve 1021 and the booster pump 1022 are opened, the water pump 1042 is closed, and at this time, after sewage generated after the reverse osmosis filter element is flushed by water flows into the wastewater passage 107 through the wastewater outlet 10g, the sewage can flow to the wastewater outlet 108 through the water through hole with the larger diameter of the wastewater solenoid valve 1071.

Optionally, the reverse osmosis filtering path 104 further includes a check valve 1045, and the check valve 1045 is disposed between the reverse osmosis filter element 103 and the pressure testing device 1043, and is configured to maintain the pressure of the reverse osmosis filtering path 104 when the waste water solenoid valve 1071 is opened.

If the check valve 1045 is not provided, when the reverse osmosis filter element 103 is flushed, since the diameter of the water passing hole is large after the waste water solenoid valve 1071 is opened, the water flow in the entire purified water passage can flow to the waste water outlet 108 through the water passing hole, which inevitably causes the water pressure of the reverse osmosis filtration passage 104 to decrease. If the pressure testing device 1043 detects a decrease in pressure and sends a signal to the control device, it may cause the control device to make a false determination that the user is fetching water. In order to avoid this, a check valve 1045 may be provided between the reverse osmosis filter element 103 and the pressure testing device 1043, which allows the water to flow from the reverse osmosis filter element 103 to the pressure testing device 1043 and prohibits the water from flowing from the reverse osmosis filter element 103 to the pressure testing device 1043, so that even if the diameter of the water passing hole is large after the waste water solenoid valve 1071 is opened, the water pressure of the reverse osmosis filtration path 104 is not changed, thereby preventing erroneous judgment of the control device.

The embodiment of the present disclosure provides a dual-core water purification system 10, when it is detected that the pressure value is decreased, the water inlet solenoid valve 1021, the booster pump 1022 and the water pump 1042 of the dual-core water purification system 10 may be simultaneously opened, such that the first purified water pre-stored in the water storage bag 1041 and the second purified water filtered by the composite filter element 101 and the reverse osmosis filter element 103 simultaneously flow to the purified water outlet 105, thereby increasing the water flow rate of the purified water outlet 105; meanwhile, the water storage bag 1041 is used for storing purified water, the cost of the whole double-core water purification system is reduced, the popularization and the use of the water purifier are facilitated, and the volume of the water storage bag 1041 for storing purified water is small, so that the volume of the whole double-core water purification system is reduced, and the condition that too much space is occupied under a kitchen is avoided.

According to an embodiment of the present disclosure, a dual-core water purifier is provided, which includes the dual-core water purifying system 10 of any of the above embodiments and a casing enclosing the dual-core water purifying system 10. When a user takes water, the water inlet electromagnetic valve 1021, the booster pump 1022 and the water pump 1042 of the dual-core water purification system 10 included in the dual-core water purifier can be simultaneously opened, so that the first purified water pre-stored in the water storage bag 1041 and the second purified water filtered by the composite filter element 101 and the reverse osmosis filter element 103 can simultaneously flow to the purified water outlet 105, and the water flow rate of the purified water outlet 105 is increased; meanwhile, the water storage bag 1041 is used for storing the purified water, so that the cost of the whole water purifier is reduced, the popularization and the use of the water purifier are facilitated, and the volume of the water storage bag 1041 for storing the purified water is smaller, so that the volume of the whole water purifier is reduced, and the condition that too much space is occupied under a kitchen is avoided.

It should be noted that, since the double-core water purifier adopts all the technical solutions of all the embodiments, all the beneficial effects brought by the technical solutions of the embodiments are also achieved, and are not described in detail herein.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This application is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

It will be understood that the present disclosure is not limited to the precise arrangements described above and shown in the drawings and that various modifications and changes may be made without departing from the scope thereof. The scope of the present disclosure is limited only by the appended claims.

Claims (10)

1. A double-core water purification system is characterized by comprising a composite filter element, a preposed filtering passage, a reverse osmosis filter element, a reverse osmosis filtering passage, a purified water outlet and a control device; the composite filter element comprises a front filter assembly, a first water inlet and a first water outlet of the front filter assembly; the reverse osmosis filter element is provided with a second water inlet and a second water outlet;

the first water inlet is connected with an external water source;

the first water outlet is communicated with a second water inlet of the reverse osmosis filter element through the pre-filtering passage;

the second water outlet of the reverse osmosis filter element is communicated with the purified water outlet through the reverse osmosis filtering passage;

the pre-filtering passage comprises a water inlet electromagnetic valve and a booster pump which are communicated, and the water inlet electromagnetic valve and the booster pump are both connected with the control device;

the reverse osmosis filtering passage comprises a water storage bag, a water suction pump and a pressure testing device which are communicated, and the pressure testing device and the water suction pump are both connected with the control device; the water storage bag stores first purified water which is filtered by the pre-filtering component and the reverse osmosis filter element in advance;

the pressure testing device is used for detecting the pressure value of the reverse osmosis filtering passage;

the control device is used for obtaining the pressure value, and when the pressure value satisfies the preset condition, instruct the water inlet solenoid valve, the booster pump with the suction pump is opened simultaneously, makes the first water purification of water storage bag storage with pass through composite filter element with the second water purification after the reverse osmosis filter element filters flows to simultaneously the water purification export.

2. The dual core water purification system of claim 1, wherein the reverse osmosis filtration circuit further comprises a branch circuit;

one end of the branch passage is communicated with the second water outlet, and the other end of the branch passage is communicated with the purified water outlet.

3. The dual core water purification system of claim 1, further comprising a post-filtration pathway; the composite filter element comprises a post-filter assembly and a third water inlet and a third water outlet of the post-filter assembly;

the second water outlet is communicated with the third water inlet through the reverse osmosis filtering passage;

the third water outlet is communicated with the purified water outlet through the rear filtering passage.

4. The dual core water purification system of any one of claims 1 to 3, further comprising a waste water passage and a waste water outlet; the reverse osmosis filter element is provided with a wastewater outlet;

the waste water outlet is connected with the waste water passage and is used for leading the waste water generated by the reverse osmosis filter element to flow to the waste water outlet through the waste water passage.

5. The dual core water purification system of claim 4, wherein the waste water pathway includes a waste water solenoid valve in a normally closed state connected to the control device; the reverse osmosis filtering passage also comprises a check valve, and the check valve is arranged between the reverse osmosis filter element and the pressure testing device;

the control device is used for indicating the wastewater electromagnetic valve to be opened when the reverse osmosis filter element is cleaned, so that wastewater generated when the reverse osmosis filter element is flushed flows to the wastewater outlet through the wastewater passage;

the check valve is used for maintaining the pressure of the reverse osmosis filtering passage when the wastewater electromagnetic valve is opened.

6. A dual core water purification system as claimed in any one of claims 1 to 3 wherein the reservoir bag is made of thermoplastic polyurethane elastomer rubber TPU.

7. A dual core water purification system as claimed in any one of claims 1 to 3 wherein the volume of the reservoir bag is 3 litres.

8. A dual cartridge water purification system as claimed in any one of claims 1 to 3, wherein the pressure test device comprises a high pressure switch.

9. The dual core water purification system of claim 3, wherein the pre-filter assembly comprises a polypropylene fiber (PP) and a carbon rod composite filter element; the post-filter assembly includes an activated carbon filter element.

10. A two-cartridge water purifier comprising the two-cartridge water purification system according to any one of claims 1 to 9.

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