KR20150007876A - Water Purifier - Google Patents

Abstract

The preset invention relates to a water purifier having increased convenience for a user. More specifically, the water purifier provides purified water processed by a filter part from raw water. According to an embodiment of the present invention, the water purifier includes a cabinet; a dispenser which forms a water discharging space on a front side of the cabinet; the filter part which produces the purified water from the raw water; and a purified water distribution unit. The purified water distribution unit includes a flow channel module that includes a plurality of flow channels formed therein and discharges the purified water entering through the flow channels; and a plurality of flow channel controlling units that control opening, closing, converting the flow channel.

Description

Water Purifier

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water purifier, and more particularly, to a water purifier that provides a user with purified water from raw water through a filter section.

In a general water purifier, raw water supplied from a water pipe is passed through a separate filtering means and then filtered to remove foreign substances contained in the raw water.

Such a water purifier can be classified into natural filtration type, direct filtration type, ion exchange water type, and reverse osmosis type depending on the purification method. Of these, the reverse osmosis type water purifier is designed to apply a predetermined pressure to the raw water, By passing water through a membrane that is a membrane, purified water, bacteria, carcinogens, etc. are separated and removed, and only purified water and dissolved oxygen are passed through, which is used in the cutting-edge science industry and cleaning of high- Is widely used for water purifiers for household and business use due to serious environmental pollution.

Various efforts have been made to improve user convenience when using such a water purifier.

Particularly, there is an increasing need for large-capacity purified water for domestic use as well as for commercial use. In order to discharge the large-capacity purified water, the thickness of the tube through which the purified water flows becomes thick, so that the number of connected parts such as fitting increases, and the tube is difficult to bend. This can lead to an increase in the volume of the water purifier and an increase in the manufacturing cost.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a water purifier with improved user convenience.

It is an object of the present invention to provide a water purifier which can easily increase the number of corks and is easy to manufacture.

Through the embodiments of the present invention, it is desirable to provide a water purifier capable of simultaneously leaving out purified water through a plurality of corks.

It is an object of the present invention to provide a water purifier provided with a flow path module capable of minimizing the connecting parts in constructing the flow path of the water purifier.

It is an object of the present invention to provide a water purifier that minimizes the point at which fitting is required to reduce leakage points.

It is an object of the present invention to provide a water purifier for eliminating odor and deterioration in airtightness due to a hermetic material such as an O-ring connecting a flow path.

It is an object of the present invention to provide a water purifier that minimizes the possibility of occurrence of internal noise due to hydraulic pressure barrier phenomenon in a flow path.

It is an object of the present invention to provide a water purifier capable of preventing an increase in manufacturing cost and a volume increase of a water purifier due to a complicated flow path configuration.

It is an object of the present invention to provide a water purifier in which the convenience of the fastening method between the flow path control unit and the fitting and the flow path module is enhanced.

It is an object of the present invention to provide a water purifier capable of easily understanding the flow path of the water purifier and modularizing the flow path so that the problem can be quickly solved when a problem occurs in the water purifier.

According to an aspect of the present invention, there is provided an air conditioner comprising: a cabinet forming an appearance; a dispenser forming an outflow space in front of the cabinet; a filter unit generating purified water from raw water; Wherein the purified water distributing unit includes a plurality of flow paths formed therein, a flow path module in which the purified water flows in and flows out through the flow path; And a plurality of flow path control units for controlling opening and closing and switching of the flow path.

The filter unit may include a plurality of filter units connected in parallel with an external water source, and the plurality of filter units may be independently connected to the inlet port of the channel module.

Wherein each of the filter units includes a plurality of filters connected in series.

The flow path module may be provided with a water purifier including a valve mount for mounting at least a part of the flow path control units of the plurality of flow path control units.

The flow path module includes a first plate that forms an upper outer surface of the flow path module, and a second plate that forms a lower outer surface of the flow path module. The flow path is formed by engagement of the first plate and the second plate A water purifier can be provided.

And a water purifier characterized in that the coupling is performed through vibration welding.

Wherein the first plate includes a protruding portion corresponding to the depressed portion, and when the first plate and the second plate are coupled with each other, the second plate includes a depression formed in the plate base, And a flow path is formed by the protruding portion and the protruding portion.

The flow path module further includes a plurality of outflow ports through which purified water flows in the flow path, and the outflow ports protrude upward or downward by a predetermined length from the first plate, The water purifier can be provided.

The inlet port is provided at one side of the flow path module, and the outlet port is provided at the other side of the flow path module.

Wherein the flow path includes a purified water flow path at room temperature and further includes at least one of a cold water flow path and a hot water flow path.

A cooling device for cooling the purified water to generate cold water and a heating device for generating hot water by heating the purified water are positioned so as to face up and down with respect to the flow path module.

The water purifier may be provided in which the purified water flowing out from the normal-temperature purified water flow path flows back to the flow path module through the cooling device or the heating device.

And a through hole is formed in the flow path module so that a tube through which the cold water or hot water flows is vertically passed through the water path.

Wherein the water purifier is a water straight type water purifier in which the purified water is directly discharged to the outside by directly using the water pressure of the external water source.

Wherein the flow path control unit mounted to the valve mount is connected to the flow path module through a fitting and the direction in which the flow path control unit and the valve mount are coupled and the direction in which the fitting and the flow path module are coupled are the same. .

Wherein the flow control unit to which the fitting is connected is coupled to the valve mount, and the fitting is also coupled to the flow path module.

Wherein the dispenser includes a plurality of corks, and the plurality of corks can simultaneously dispense purified water.

Wherein the plurality of corks include a first cock to supply only purified water at a normal temperature, a second cock to selectively supply cold water and a purified water at room temperature, And a third cock adapted to selectively supply purified water only at room temperature.

The water purifier may further include a door provided on a front surface of the cabinet for selectively exposing the dispenser to the outside of the cabinet, and an external dispenser provided in front of the door.

The water purifier may be provided such that the door is closed for use of the external dispenser and opened for use of the dispenser.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a water purifier with improved user convenience.

Through the embodiments of the present invention, it is possible to provide a water purifier that can easily increase the number of corks and is easy to manufacture.

Through the embodiments of the present invention, it is possible to provide a water purifier that can purify water at the same time through a plurality of corks.

It is possible to provide a water purifier having a flow path module capable of minimizing the connecting parts in constructing the flow path of the water purifier through the embodiments of the present invention.

Through the embodiments of the present invention, it is possible to provide a water purifier that minimizes the point at which the fitting is required and reduces the leakage point.

Through the embodiments of the present invention, it is possible to provide a water purifier for eliminating odor and deterioration in airtightness due to hermetic materials such as O-rings connecting the flow paths.

It is possible to provide a water purifier that minimizes the possibility of occurrence of internal noise due to the hydraulic pressure barrier phenomenon in the oil passage through the embodiment of the present invention.

It is possible to provide a water purifier capable of preventing an increase in manufacturing cost and a volume increase of a water purifier due to a complicated flow path configuration through the embodiments of the present invention.

Through the embodiments of the present invention, it is possible to provide a water purifier in which the convenience of the fastening method between the flow path control unit and the fitting and the flow path module is enhanced.

It is possible to provide a water purifier capable of easily understanding the flow path of the water purifier and modularizing the flow path so that the problem can be quickly solved when a problem occurs in the water purifier.

1 is a perspective view illustrating a water purifier according to an embodiment of the present invention;
FIG. 2 is a perspective view showing a water purifier in a state in which a door is opened; FIG.
Figure 3 shows various uses of the dispenser;
4 is a side view showing a flow path connection relation in the water purifier;
5 is a perspective view showing a flow path connection relation in the water purifier;
6 is an exploded view of a flow path module;
7 is a view showing a coupling relation of a valve, a fitting, and a flow path module;
8 is a perspective view showing a flow path module equipped with a flow control unit;
9 is a view showing the flow direction of the purified water in the flow path module;
10 is a piping diagram showing the relationship between the flow path and the valve in the water purifier.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

It is to be understood that within the scope of the appended claims, the invention may be practiced otherwise than as specifically described within the spirit and scope of the appended claims. Of course.

Embodiments of the present invention relate to a water purifier, i.e., a water purifier for purifying raw water such as tap water to supply drinking water. The raw water may be purified water through a filter unit (not shown), and the purified water may include hot water, cold water, or an ordinary temperature constant. Accordingly, such water purifiers may include an apparatus for supplying a beverage such as coffee using an integer, and may also include an apparatus for generating and supplying ice using purified water.

In order to generate an integer, it is possible to pass through processes such as precipitation, filtration and sterilization, and it is general that harmful substances are removed through these processes.

In general, the water purifier may be equipped with various filters to purify the raw water. These filters can be classified into a sediment filter, an activated carbon filter, a UF hollow fiber membrane filter, an RO membrane filter or the like according to their functions.

The sediment filter may be a filter for precipitating large contaminants or suspended matters in raw water, and the activated carbon filter may be a filter for adsorbing and removing small contaminants, residual chlorine, volatile organic compounds, and odor generating factors .

Generally, two activated carbon filters may be provided. That is, a pre-activated carbon filter provided on the raw water side and a pre-activated carbon filter provided on the purified water side may be provided. The post-activated carbon filter may be provided to improve the taste of water by removing odor inducing substances that mainly affect the taste of purified water.

Both the UF hollow fiber membrane filter and the RO membrane filter are generally used selectively.

RO membrane filters can be used to effectively remove heavy metals, ionic substances and microorganisms by applying reverse osmosis membranes. However, such RO membrane filters are expensive and have a problem of discarding a large amount of raw water. In addition, there is a problem that minerals and components useful for the human body are also removed.

On the other hand, UF hollow fiber membrane filters can effectively remove ionic substances and microorganisms while maintaining the beneficial minerals in the human body. In addition, it is possible to minimize the raw water that is inexpensive and wasted as compared with the RO membrane filter. For example, only 40% of the raw water flowing into the RO membrane filter can be converted to an integer, and the raw water flowing into the UF hollow fiber membrane filter can be converted to a 100% integer.

However, there is a problem that it is difficult to effectively remove heavy metals through the UF hollow fiber membrane filter. Accordingly, there is a problem that it is difficult to provide a water purifier that can use tap water or ground water in a contaminated area as raw water.

In recent years, demand for water purifiers has increased significantly. Therefore, there are problems that various requirements are generated and it is difficult to satisfy at the same time.

For example, it is possible to remove heavy metals by applying an RO membrane filter, but it is difficult to secure the flow rate of purified water. That is, it takes a very long time to obtain a desired amount of purified water.

On the other hand, UF hollow fiber membrane filter can secure high flow rate, but it is difficult to use tap water in groundwater or contaminated area as raw water because it is difficult to remove heavy metals in water.

Therefore, removal of heavy metals and securing of high flow rate were inevitably regarded as contradictory problems. This is because it is difficult to obtain a high flow rate when RO membrane filter is used to remove heavy metals and heavy metal removal is difficult when UF hollow fiber membrane filter is used to secure high flow rate.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

1 shows an example of a water purifier 10 according to an embodiment of the present invention. As shown, the external structure or shape of the water purifier may be similar or identical to a conventional water purifier.

The water purifier 10 may include a cabinet, a dispenser 31 for supplying drinking water in front of the cabinet, and a tray 14 disposed under the dispenser. The tray 14 is a storage space for receiving cups or water bottles and receiving residual water.

The dispenser 31 may include one or more corks 35. In the cork 35, hot water, cold water, or purified water at room temperature is selectively discharged.

The external dispenser 31 and the tray 14 shown in Fig. 1 are provided in front of the cabinet.

On the other hand, as shown in FIG. 2, as the door 4 is opened, another dispenser may be provided inside the cabinet. When the door 4 is opened, the dispenser inside the cabinet can be exposed to the outside of the cabinet.

2, the dispenser and the tray are referred to as an external dispenser 31, an internal dispenser 3, an external tray 14, and an internal tray 12, respectively, in the case where dispensers are provided inside and outside the cabinet, respectively Be able to

At least a part of the outer dispenser 31 may be provided on at least a part of the front surface of the door 4. FIG. 1 shows an example in which a cock 35 is provided on the front surface of the door 4. FIG.

According to the present embodiment, the inner dispenser 3 may be formed on the rear side of the door 4. This will be described with reference to FIG.

As shown, an internal dispenser 3 is provided inside the cabinet. The door 4 may be provided to selectively open and close the space outside the cabinet.

That is, when the door 4 is closed, the inner dispenser 3 is isolated from the cabinet. When the door 4 is opened, the inner dispenser 3 may be exposed to the outside of the cabinet.

As shown in FIG. 1, if the dispenser is always exposed to the outside, it is convenient because the access is very easy. However, this can easily lead to exposure to external contaminants. As shown in FIG. 2, when the dispenser is selectively exposed to the outside by the door 4, the possibility of exposure to external contaminants can be reduced. This is because, if the dispenser is not used, the door 4 can be closed to isolate the dispenser from the outside. Of course, when the internal dispenser 3 is used in a large amount, the door 4 can be kept in an open state, so there is no great restriction on its use.

On the other hand, a dispenser may be provided only in the front of the cabinet. Further, in the case of a water purifier in which a large amount of water is simultaneously discharged, a dispenser having a plurality of corks may be provided in front of the cabinet.

2, when the door 4 is opened, the door 4 may be positioned above the outer tray 14. [ Therefore, the external tray 14 can no longer function as a tray.

Here, the tray function means receiving the residual water, and it is possible to prevent the residual water from flowing out of the cabinet. Of course, the tray function could include a table function to support cups or water bottles.

When the internal dispenser 3 is used, the door 4 can function as a tray. Assuming a tray function to support a cup or a water bottle, it is preferable that the tray is substantially fixed horizontally to the paper.

Hereinafter, an embodiment in which the external dispenser 31 is provided in the door 4 will be described in detail.

1, the cock of the external dispenser 31 is provided in the door 4, and the door 4 can be opened as shown in FIG. Therefore, the purified water inside the cabinet must be able to be supplied to the outer cock 35 through the rotatable door 4.

In FIG. 1, purified water, hot water and cold water can be selectively supplied through one outer cock 35. Therefore, water, hot water and cold water can be selectively supplied through one external dispenser 31. [

On the other hand, unlike FIG. 1, a plurality of corks may be provided. In this case, the plurality of corks may be installed on the door 4.

3, the inner dispenser 3 may include a first cock 331, a second cock 332, and a third cock 333. As shown in FIG. In the plurality of corks, the purified water from the raw water through the filter unit (not shown) can simultaneously flow out.

The constant may be room temperature, cold water or hot water. The dispenser may include a plurality of dispensers having various functions. More specifically, according to one embodiment of the present invention, the internal dispenser 3 includes a first cock 331 for selectively supplying hot water and purified water, a second cock 332 for supplying only purified water, And a third cock 333 provided to selectively supply only the integer.

In addition, the internal dispenser 3 includes a first cock 331 provided to supply only purified water, a second cock 332 provided to selectively supply cold water and purified water, and a third cock 332 provided to selectively supply purified water. And may include a cock 333.

It goes without saying that the configuration of the cock is not limited to the embodiment described above.

Meanwhile, in the case of the large capacity water purifier 10, a plurality of filters (not shown) may be connected in parallel. A filter unit (not shown) provided in parallel is connected in series with a flow path to form a plurality of flow paths. The flow path may include at least one of a normal-temperature purified flow path 531, a cold water flow path 532, and a hot water flow path (not shown).

It is preferable that a plurality of filter portions are provided in order to maintain a flow rate when a large number of corks simultaneously flow out. When a plurality of filter units are connected in parallel, a complicated flow path is formed more than the flow path by one filter unit. Even when a plurality of corks having a plurality of various functions are formed without a plurality of filter units (not shown), a complicated flow path configuration is unavoidable.

Therefore, it is necessary to solve the difficulties in the above-mentioned flow path fabrication process and to minimize the number of connecting parts for connecting the valve and the tube. Also, in order to minimize the leakage point by minimizing the point where the fitting is required, and to prevent the generation of odor and the deterioration of the airtightness due to the hermetic material such as the O-ring connecting the oil lines, the present invention provides a water purifier 10 including a flow path module .

In the present embodiment, it is possible to provide a water purifier that receives raw water through an external water source and converts the raw water into purified water. It is possible to provide the water purifier which can take out the purified water as it is or can convert it to hot water or cold water to get out. In addition, a water purifier capable of sterilizing various internal pipes by using steam can be provided. Therefore, such a water purifier can be called a direct water purifier.

The embodiment of the present invention is not limited to the direct water purifier. However, the present invention is more advantageous for a direct water type water purifier in which the flow path can be more complicated than the low water type water purifier.

4 and 5 are side views of the water purifier 10 having the flow path module 5 according to the present invention. This will be described below with reference to Figs. 4 and 5. Fig.

The purified water distribution unit 2 may include a flow path module 5 and a flow path control unit 8. According to an embodiment of the present invention, the constant passing through the filter unit (not shown) flows into the flow path module 5 and flows to each flow path in the flow path module 5 according to the purpose. The flow is controlled by the flow control unit 8.

The flow control unit 8 may be mounted directly on the flow path module 5 as shown in FIG. According to an embodiment of the present invention, the flow path control unit 8 may be constituted by a plurality of valves. The flow control unit 8 may include a cold water generation valve 828 and a hot water generation valve 824 for discharging the purified water to the hot water tank or the cold water tank.

In addition, it may include a hot water supply valve 827, a first cold water supply valve 820, and a second cold water supply valve 821 for discharging cold water or hot water to the cock. A first purified water supply valve 822 and a second purified water supply valve 823 for supplying purified water at a normal temperature to the coke.

On the other hand, when the purified water at room temperature is directly discharged to the coke, a valve related to purified water supply at normal temperature may not need to be mounted on the flow path module.

The flow control unit 8 may include a drain valve 826 for discharging residual water.

In addition, the water purifier may include a water outlet valve 81 for ultimately controlling the dispenser outflow at a point adjacent to the dispenser.

And the constants flowing out from the flow path module finally arrive at the dispenser under the control of the outflow valve. Therefore, the control of the flow control unit 8 and the outflow valve 81 can be performed simultaneously.

The positions of the flow control unit 8 and the water outlet valve 81 are not limited to the above-described embodiment, but can be modified in accordance with the shape of the water purifier. Particularly, in order to efficiently control the flow path, the position where the flow control unit 8 is mounted can be variously changed.

However, in order to reduce the number of fittings to be coupled between the flow control unit and the tube, it is preferable to be mounted on the upper surface of the flow path module. Details of the flow channel module will be described later.

Referring to FIG. 4, a flow path is formed by the flow path module 5, and the flow path is controlled by the flow path control unit 8. The flow control unit 8 may include a supply valve that is directly mounted on the flow path module 5 and controls the cold water flow path 532, the hot water flow path (not shown), and the purified water flow path 531 at normal temperature.

The outflow valve 81 for controlling the outflow of the inner dispenser 3 is connected to the coke header 330 which is the rotation center of the cock 33. The outflow valve 81 is connected to the first outflow valve A valve 812, a second water outlet valve 813, and a third water outlet valve 814 may be provided.

It is obvious that the number of the outflow valves is not limited and the flow path module can be applied to a water purifier in which only a dispenser provided with a plurality of corks is provided in front of the cabinet.

5, the external water outlet valves 810 and 811 are installed at the front of the cabinet to control the outflow of the external cock 35. Referring to FIG. That is, the first and second external water outlet valves 810 and 811 correspond to the two cocks. The first external water outlet valve 810 controls the water outlet of the hot water or the cold water and the second external water outlet valve 811 can control the water outlet of the hot water.

In addition, the water purifier 10 is provided with a cooling device 6 for cooling the purified water to generate cold water, and a heating device 7 for generating hot water by heating the purified water. The cooling device 6 includes a cooler and a cold water bottle. More specifically, the heating device 7 may include a hot water bottle 72 and a heater 71.

It is preferable that the cooling device 6 and the heating device 7 are positioned so as to be vertically opposed to each other with the flow path module 5 as a center.

More specifically, in the present embodiment, the tube should be connected upward to flow the purified water to the heating device 7 located at the upper part with the flow path module 5 as a center. On the other hand, in order to generate cold water, the tube is connected in the downward direction to send the purified water to the cooling device (6) opposite to the heating device (7).

That is, since the flow path module 5 is disposed between the cooling device and the heating device, the cold water flow path and the hot water flow path can be arranged vertically. This is for the hot water channel and the cold water channel not to be bypassed but to be out through the shortest path. In addition, the inner space of the water purifier 10 can be efficiently utilized.

The flow path module 5, the flow path control unit 8 and the water outlet valve 81 are connected by a tube and a fitting 9. The fitting can be composed of an elbow fitting, a T fitting, a conversion fitting, a Y fitting, etc., and can be used as a configuration suitable for a channel according to a user's selection.

As shown in FIGS. 4 and 5, when the flow path of the water purifier 10 including the plurality of corks having various functions is very complicated, when the flow path is formed by the flow path module 5, It can be seen that the volume of the flow path occupied is rapidly reduced.

The flow channel module 5 will be described in more detail with reference to FIG.

The flow path module 5 is formed by a combination of a first plate 51 forming an upper outer surface of the flow path module 5 and a second plate 52 forming a lower outer surface of the flow path module 5 .

The bonding increases the bonding strength by chemical bonding between materials, bonding by vibration welding, and the like, thereby preventing the water from leaking out of the flow path.

The second plate 52 forming the lower outer surface of the flow path module 5 includes a depression 521 formed from the plate base 520. The first plate 51 is also connected to the depression 521, A corresponding raised portion 511 is provided. The depressed portion 521 and the raised portion 511 can form a flow path in the flow path module 5 by coupling the first plate 51 and the second plate 52.

The raised portion 511 is formed at a position corresponding to the depressed portion 521 and the upper surface of the first plate 51 is raised corresponding to the width of the depressed portion 521. That is, the back surface of the first plate 51 is recessed as the upper surface is raised to form a space in the flow path module 5 by the engagement of the first plate 51 and the second plate 52. Therefore, the space can be a channel.

In the flow path module according to the present invention, since the depressions 521 for forming the flow paths are formed on the respective plates and the plates are combined, the difficulty in bending the thick tubes is eliminated. That is, the process of manufacturing the flow path can be greatly reduced and simplified.

In addition, no matter how complicated the flow path is, the fitting is unnecessary at the point where the flow path of the flow path module 5 is bent, so that the number of required fittings and tubes is greatly reduced. Therefore, the effect of the present invention is maximized as the water purifier having a complicated flow path.

The flow path in the flow path module 5 includes at least one of a normal-temperature purified water flow path 531, a hot water path (not shown) and a cold water path 532. In particular, it is preferable to further include at least one of the cold water flow path 532 including the purified water flow path 531 at room temperature.

6 and 7, a valve mount 57 for mounting the flow control unit 8 to the flow path module 5 may be coupled to the flow path module 5 according to an embodiment of the present invention. Particularly, the valve mount 57 is preferably mounted on the upper surface of the first plate 51.

The valve mount 57 is formed to protrude from the upper surface of the first plate 51 by a predetermined length so as to secure a coupling height between the flow control unit 8 and the fitting 9 connected horizontally .

According to the embodiment of the present invention, the purified water passing through the filter unit (not shown) first flows into the flow path module 5 through the tube. The purified water that has not undergone the cooling process or the heating process is taken out of the flow path module 5 and passes through the cooling device 6 or the heating device 7.

That is, the purified water flowing out from the normal-temperature purified water flow path 531 flows into the flow path module 5 through the cooling device or the heating device. Therefore, it is preferable to provide a through-hole through which the tube, through which the cold water at room temperature flows out to the cooling device 6 or the heating device 7, is provided. The through hole may include at least one of a first through hole (59) and a second through hole (60).

At this time, when the heating device 7 is located at the upper part with respect to the flow path module 5, the through holes 59 and 60 for hot water entry and exit may be unnecessary.

In addition, the flow path module 5 is provided with at least one inlet through which purified water flows from raw water through a filter unit (not shown). The inlet may include at least one of a first inlet 551, a second inlet 552, and a third inlet 519. If a plurality of filter units (not shown) are connected in parallel, it is preferable that the number of the inlets is also a plurality.

On the other hand, the purified water immediately after passing through the filter unit (not shown) flows into the inlet port, and there may be one inlet port into the flow channel module, but a plurality of outlets through which the purified water is discharged can be provided to the dispenser.

The flow path starts from the inlet port, and the flow path may be branched while branching in one direction from one flow path.

6, when the first plate 51 and the second plate 52 are coupled to each other, a first inlet port 551 and a second inlet port 552 are formed in the flow path module 5, .

7, a first inlet pipe 553 and a second inlet pipe 554 are formed when the tube or the fitting 9 is coupled to the inlet. The first inlet pipe 553, the second inlet pipe 553, The purified water immediately after passing through the filter unit (not shown) may be introduced into the pipe 554.

In addition, the flow path module 5 includes a plurality of outflow ports through which the purified water in the flow path flows. The outlet may include at least one of a first outlet 514, a second outlet 515, a third outlet 516, a fourth outlet 517, and a fifth outlet 518.

The outlet may be formed to protrude upward or downward from the first plate 51 in order to secure a coupling length with the fitting 9 provided between the flow control units 8

In the outlet, the constants in the flow path can be taken out, and the type and number of the outlet can be changed according to the configuration of the flow path.

In an embodiment of the present invention, the first outlet, the third outlet, and the fifth outlet 514, 516, and 518 correspond to the outlets for discharging purified water to the inner dispenser 3. The second outlet 515 is for allowing the coolant of the room temperature in the flow path module 5 to flow out to the cooling device.

The purified water exiting through the second outlet 515 may flow to the cooling device 6 through the tube passing through the first through hole 59. Further, the first purified water supply valve 822 exits the purified water at room temperature from the fourth outlet 517 to the third outlet 516, which can be discharged to a tube connected to the second cock of the inner dispenser.

The cold water passing through the cooling device 6 flows into the flow path module 5 again by a tube passing through the second through hole 60 and the introduced cold water flows through the third inlet 516 to the flow path module 5). ≪ / RTI > It can be seen that cold water can be discharged through the third outlet 516 to the inner dispenser.

Meanwhile, the flow control unit 8 and the outlet may be connected to each other by a fitting 9 mounted on the flow path module 5. Particularly, the flow control unit 8 can call the flow of the purified water in the flow path module 5, and it can be known in advance that the method of mounting the flow path control unit 8 according to the function of the water purifier can be varied.

7 shows the coupling relationship between the flow path control unit 8, the fitting 9 and the flow path module 5. As shown in Fig. The flow path control unit 8 mounted on the valve mount 57 and the flow path module 5 are connected to each other through a fitting 9 and the flow path control unit 8 is connected to the valve mount 57 7) and the fitting direction of the fitting 9 and the flow path module 5 are the same.

When the fitting 9 is first coupled to the flow path control unit 8 and then the flow path control unit 8 connected to the fitting 9 is fastened to the valve mount 57, And is connected to the flow path module 5. Therefore, the connection direction of the connection components such as the fitting 9 and the flow path module 5, and the flow direction of the flow path control unit 8 and the flow path module 5 will be the same. It is obvious that the workability of the product manufacturing can be improved if the valve fastening and the fitting fastening are performed at the same time.

This fastening method saves time and effort compared to the case of fastening the tube and the flow path control unit 8 by the O-ring or the like. Since the flow path control unit 8 and the fitting 9 can be joined at the same height, It can be seen that the volume can be minimized.

Fig. 8 is a perspective view showing a state in which the plurality of flow path control units 8 are mounted on the flow path module 5. Fig. Fig. 9 shows the flow of the flow path in the water purifier in the flow path module 5 equipped with the flow path control unit 8, and an embodiment of the present invention will be described based on this flow.

The valve of the water purifier can be roughly divided into a water outlet valve 81 for controlling the outflow of the dispenser and a flow control unit 8 for controlling the passage of the flow channel module 5 in the flow channel module 5. The purified water immediately after passing through the filter unit (not shown) flows into the inflow pipes 553 and 554.

The purified water can directly supply the purified water at the room temperature to the internal dispenser through the first outlet 514, and the purified water can be controlled by the first water outlet valve 812 positioned at the internal dispenser 3 side. When the second purified water supply valve is opened, purified water can be supplied to the external dispenser 31 by the purified water supply pipe 831. On the other hand, when the second purified water supply valve is closed, the purified water can be discharged only to the fifth outlet 518. When the first purified water supply valve is opened, it can be seen that the purified water at room temperature is supplied to the third outlet 516.

The hot water generation valve 824 can switch the flow path so that the purified water at room temperature flows out to the heating device 7. The purified water that has been made hot water through the heating device 7 is sent to the hot water supply pipe 829 under the control of the hot water supply valve 827 so that hot water can be supplied to the external dispenser 31.

On the other hand, it is necessary to maintain the temperature of the first cup when the hot water is supplied at a predetermined temperature or higher. This is controlled by the drain valve 826 of the flow path module 5. That is, when the user desires to leave hot water, the drain valve 826 is opened and the hot water supply valve 827 is closed. Therefore, the water that is below a certain temperature over time is discharged to the outside. At this time, the waste water can be discharged to the tray. After the remaining water is discarded, the hot water supply valve 827 is opened and the drain valve 826 is closed, whereby hot hot water is supplied.

In the embodiment of the present invention, the valve for supplying hot water to the inner dispenser 3 is not constituted. However, it is obvious that a valve for supplying hot water to the inner dispenser 3 can be provided if necessary.

On the other hand, the cold water is discharged by the cold water supply valves 820, 821 and the cold water generation valve 828. When the cold water generating valve 828 is opened, the purified water at room temperature passes through the cooling device 6 through the first through hole 59. The purified water that has been chilled through the cooling device flows into the flow path module 5 again through the second through hole 60 and the first cold water supply valve 820 discharges the cold water to the third outlet 516, (3). On the other hand, the second cold water supply valve 821 supplies cold water to the external dispenser 31 through the cold water supply pipe 830.

10 is a schematic piping diagram of an embodiment of the present invention. A indicated by a dotted line shows the valve configuration in the flow path module 5, and the outside of A shows a valve provided in the dispenser portion.

Since the flow path module 5 of the present invention is constituted in the same manner as the flow path of the water purifier 10 is provided on a plane like the above piping, it is easy to understand how the flow path is configured regardless of the complicated flow path.

That is, it is possible to provide a water purifier capable of easily understanding the flow path of the water purifier and modularizing the flow path so that the problem can be quickly solved when a problem occurs in the water purifier.

Even if the flow path is very complicated, the flow path can be formed and coupled to the upper and lower injection molds. Also, since the flow path formed on the injection mold does not require fitting even at the point where the eur is bent, it is possible to eliminate the problem that occurs in the process of bending and fitting the tube.

Therefore, the mass productivity of the product can be increased, the assembling process can be simplified and simplified, and this can be said to be linked to the improvement of the service quality of the product.

1: cabinet 2: constant dispensing unit
3: dispenser 4: door
5: flow path module 6: cooling device
7: Heating device 8: Flow control unit
9: Fitting 10: Water purifier
11: tube 35: outer cock
57: valve mount 59, 60: through hole a, through hole b

Claims (34)

A cabinet forming an appearance;
A dispenser forming an outflow space in front of the cabinet;
A filter unit for generating an integer from the raw water; And
An integer distribution unit,
The integer distribution unit
A flow path module in which a plurality of flow paths are formed inside and the purified water flows in and flows out through the flow path; And
And a flow control unit that opens and closes the flow path. The method according to claim 1,
Wherein the filter unit is provided in parallel with an external water supply source,
Wherein the plurality of filter units are independently connected to an inlet port of the flow path module. 3. The method of claim 2,
Wherein each of the filter units includes a plurality of filters connected in series. The method according to claim 1,
The flow-
A first plate defining an upper outer surface of the flow path module;
And a second plate forming a lower outer surface of the flow path module,
Wherein the flow path is formed by engagement of the first plate and the second plate. 5. The method of claim 4,
Wherein the coupling is performed through vibration welding. 5. The method of claim 4,
Wherein the second plate
Plate base;
And a depression formed in the plate base,
The first plate is provided with a protruding portion corresponding to the depressed portion
And a channel is formed by the depressed portion and the raised portion when the first plate and the second plate are coupled. 7. The method according to any one of claims 1 to 6,
The flow-
At least one inlet through which the purified water immediately after passing through the filter flows; And
And a plurality of outlets through which the purified water in the flow path flows out. 8. The method of claim 7,
Wherein all the constants that have passed through the filter from the raw water flow into the flow path module and are flown out. 9. The method of claim 8,
Wherein the inlet port is provided at one side of the flow path module, and the outlet port is provided at the other side of the flow path module. 10. The method of claim 9,
Wherein the number of outflow ports of the flow path module is larger than the number of outflow ports of the flow path module. 8. The method of claim 7,
The flow path includes:
Wherein the water purifier further comprises at least one of a cold water passage and a hot water passage. 12. The method of claim 11,
Wherein a cooling device for cooling the purified water to generate cold water and a heating device for generating hot water by heating the purified water are positioned so as to be vertically opposed to each other with respect to the purified water distribution unit. 13. The method of claim 12,
The constant in the cold water passage or the hot water passage,
Wherein the purified water flowing out from the purified water flow path at the room temperature flows into the flow path module through the cooling device or the heating device. 14. The method of claim 13,
Wherein a through hole is formed in the flow path module so that a tube through which the cold water or hot water flows is vertically passed through the channel module. 8. The method of claim 7,
Wherein the water purifier is a direct water type water purifier in which the purified water is directly taken out by directly using the water pressure of the external water source, A cabinet forming an appearance;
dispenser;
A filter unit for generating an integer from the raw water; And
An integer distribution unit,
The integer distribution unit
A flow path module in which a plurality of flow paths are formed inside and the purified water flows in and flows out through the flow path; And
And a flow control unit for opening and closing the plurality of flow paths,
Wherein the flow path module includes a valve mount for mounting the flow path control unit. 17. The method of claim 16,
The flow-
A first plate defining an upper outer surface of the flow path module; And
And a second plate forming a lower outer surface of the flow path module,
Wherein the flow path is formed by engagement of the first plate and the second plate. 18. The method of claim 17,
The flow-
At least one inlet port through which the purified water immediately after passing through the filter section flows; And
And a plurality of outlets through which the purified water in the flow path flows out,
Wherein the outlet is formed by projecting a predetermined length upward from the first plate to secure a coupling length with a fitting provided between the flow control units. 17. The method of claim 16,
The flow-
At least one inlet port through which the purified water immediately after passing through the filter section flows; And
A plurality of outlets through which the purified water in the flow path flows; . 20. The method of claim 19,
Wherein all the constants passing from the raw water through the filter section flow into the flow path module and are discharged. 20. The method of claim 19,
Wherein the inlet port is provided at one side of the flow path module, and the outlet port is provided at the other side of the flow path module. 22. The method of claim 21,
Wherein the number of outflow ports of the flow path module is larger than the number of outflow ports of the flow path module. 18. The method of claim 17,
Wherein the valve mount is formed on an upper surface of the first plate. 17. The method of claim 16,
The valve mount
Is formed protruding from the upper surface of the first plate by a predetermined length in order to secure a coupling height between a flow control unit to be mounted and a fitting connected horizontally. 17. The method of claim 16,
A flow path control unit mounted on the valve mount and the flow path module are connected through a fitting,
The direction of engagement between the flow path control unit and the valve mount,
Wherein the fitting direction of the fitting and the flow path module are the same. 26. The method of claim 25,
Wherein the channel control unit connected to the fitting is coupled to the valve mount and the fitting is also coupled to the flow path module. 17. The method of claim 16,
The flow path includes:
Wherein the water purifier further comprises at least one of a cold water passage and a hot water passage. 28. The method of claim 27,
Wherein a cooling device for cooling the purified water to generate cold water and a heating device for generating hot water by heating the purified water are positioned so as to face up and down with respect to the flow path module. 29. The method of claim 28,
Wherein a through hole is formed in the flow path module so that a tube through which the cold water or hot water flows is vertically passed through the channel module. 30. The method of claim 29,
The constant in the cold water passage or the hot water passage,
Wherein the purified water flowing out from the purified water flow path at the room temperature flows into the flow path module through the cooling device or the heating device. 31. The method according to any one of claims 16 to 30,
Wherein the dispenser comprises:
Comprising a plurality of cocks,
Wherein the plurality of corks are capable of simultaneously leaving constant numbers. 32. The method of claim 31,
The plurality of corks
A first cock adapted to supply a constant temperature constant;
A second cock adapted to selectively supply cold water and purified water at room temperature; And
A third cock adapted to selectively supply a constant temperature constant; And a water purifier. 32. The method of claim 31,
A door provided on a front surface of the cabinet to selectively expose the dispenser to the outside of the cabinet; And
And an external dispenser provided in front of the door. 34. The method of claim 33,
The door
Wherein the water purifier is closed for use of the external dispenser and opened for use of the dispenser.

Images