KR20150068172A - Water purifier - Google Patents

Abstract

The present invention relates to a water purifier. The water purifier according to an embodiment of the present invention comprises a base forming the bottom; a middle frame arranged on an upper side of the base; and a flow path conversion module arranged between the base and the middle frame, supporting weight applied from the middle frame, and including multiple valves to control the flow path.

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 including a channel switching module capable of supporting a load and regulating a flow path.

Recently, the use of water purifiers in various spaces including homes has been rapidly spreading in order to effectively obtain clean purified drinking water. A water purifier is a device for filtering natural water such as tap water or ground water (hereinafter referred to as "raw water"), and filters raw water through several filters to remove foreign matter or harmful substances contained in the raw water Thereby providing drinking water.

In addition to the function of providing cold water or hot water, the water purifier can have a plurality of filters to filter various components. In recent years, it has been known that the body's active oxygen, which is caused by stress and environmental pollution, And it has been pointed out that it promotes aging. Therefore, it has been suggested that drinking hydrogen-rich reduced water helps to maintain health by removing active oxygen in the body. Accordingly, there has been a water purifier that is provided to convert the purified water that has passed through the filter device into reduced water and supply it to the user. In order to provide such a variety of constants, a plurality of valves capable of controlling various flow paths are required.

However, conventionally, a plurality of valves can not be efficiently arranged, and the arrangement of the inside of the casing is complicated, resulting in a problem of inferior space efficiency.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a water purifier for integrally managing a plurality of flow paths.

Another object of the present invention is to provide a water purifier which is easy to assemble and repair by simplifying the internal structure.

Another object of the present invention is to provide a channel switching module that simultaneously performs a channel control function and a load supporting function.

Another object of the present invention is to provide a water purifier capable of minimizing the external appearance by improving the efficiency of space use.

The problems of the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a water purifier including: a base defining a bottom surface; A middle frame disposed above the base; And a flow path switching module disposed between the base and the middle frame for supporting a load applied from the middle frame and having a plurality of valves installed to control the flow path.

The details of other embodiments are included in the detailed description and drawings.

According to the present invention, there is one or more of the following effects.

First, since a plurality of valves are gathered, there is an advantage that the flow path can be integrally controlled.

Second, since the valve arrangement is optimized to simplify the structure, assembly and repair are facilitated.

Third, since a load supporting function can be performed, there is also an advantage that a separate front frame is not necessary.

Fourth, there is an advantage that the volume is reduced because the number of parts is reduced and space utilization is increased.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a perspective view illustrating an internal structure of a water purifier according to an embodiment of the present invention.
2 is an exploded perspective view of a water purifier according to an embodiment of the present invention.
3 is a perspective view of a channel switching module according to an embodiment of the present invention.
4 is a perspective view illustrating the arrangement of the valves according to one embodiment of the present invention.
5 is a rear view of the channel switching module according to an embodiment of the present invention.
6 is a plan view of a valve disposed in an inclined portion according to an embodiment of the present invention.
7 is a water pipe diagram expressing the function of the channel switching module according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention and the manner of achieving them will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. To fully disclose the scope of the invention to those skilled in the art, and the invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout the specification.

Hereinafter, the present invention will be described with reference to the drawings for explaining a water purifier according to embodiments of the present invention.

1 is a perspective view illustrating an internal structure of a water purifier according to an embodiment of the present invention. 2 is an exploded perspective view of a water purifier according to an embodiment of the present invention.

1 and 2, a water purifier according to an embodiment of the present invention includes a base 1 forming a bottom surface; A middle frame 3 disposed on the upper side of the base 1; And a flow path switching module 100 disposed between the base 1 and the middle frame 3 to support a load applied from the middle frame 3 and to control a flow path by mounting a plurality of valves 110 . The base 1 is disposed below the water purifier. The base 1 is arranged to face the bottom surface. The base (1) supports the rear frame (5). The base 1 supports the channel switching module 100. The rear frame 5 is vertically erected on the base 1. The rear frame 5 supports the middle frame 3. The middle frame 3 is connected to the rear frame 5 in a vertical direction. The middle frame 3 supports a filtration unit and a water storage tank 7 to be described later.

The flow path switching module 100 includes a plurality of valves 110. A plurality of valves 110 control the flow path. The flow path switching module 100 supports the middle frame 3 with a load. The flow path switching module 100 transfers the load of the middle frame 3 to the base 1. The middle frame 3 and the base 1 are arranged substantially in a flat state and the flow path switching module 100 is arranged substantially perpendicular to the middle frame 3 and the base 1. [ The flow path switching module 100 receives a compressive load from the base 1 and the middle frame 3.

The water purifier according to an embodiment of the present invention includes a filter 6 for filtering raw water; And a water storage tank 7 for exchanging the purified water and heat energy discharged from the filter 6 and the middle frame 3 has a filter insertion portion 8 for supporting the filter 6 and a water storage tank 7 (9). ≪ IMAGE > The water purifier may include a filtration part. The filtering section includes a plurality of filters (6). The filtration unit may include a sediment filter 6, a pre-carbon filter 6, a reverse osmosis membrane filter 6, a post- carbon filter and various types of filters 6 including nano-filters. The type, number, and order of the filters 6 are not limited to the filtering System or the filtration performance required for the water purification apparatus.

For example, a pretreatment composite filter 6 in which a sediment filter 6 and a free carbon filter 6 are integrated may be used. In place of the reverse osmosis membrane filter 6, an ultrafiltration filter 6 . It is also possible to provide a micro filter 6 or another functional filter 6 instead of or in addition to the filter 6. [

The sediment filter 6 is capable of filtering foreign matter and suspended matters contained in raw water by applying a nonwoven fabric. The free carbon filter 6 is capable of filtering chlorine components and odors contained in raw water by applying surfactant charcoal. The reverse osmosis membrane filter 6 can filter fine particles of about 0.001um. The post-carbon filter 6 is relatively more excellent in the attraction force than that of the surface activated carbon of the pre-carbon filter 6, so that the pigment and odor can be removed. The hollow fiber membrane filter (6) can filter the bacteria contained in the raw water by applying a thread-like membrane having an empty center.

3 is a perspective view of a channel switching module according to an embodiment of the present invention. 4 is a perspective view illustrating the arrangement of the valves according to one embodiment of the present invention.

3 to 4, the flow path switching module 100 according to an embodiment of the present invention includes a load supporting part 130 mounted on the valve 110 and standing between the middle frame 3 and the base 1, . The flow path switching module 100 includes a valve 110 for interrupting the flow path and a load supporting portion 130 equipped with the valve 110. The load supporting portion 130 is disposed between the middle frame 3 and the base 1. The load supporting portion 130 receives a compressive load from the middle frame 3 and the base 1. The longitudinal length of the load supporting portion 130 may be larger than the dimension of the cross sectional surface of the load supporting portion 130. [

The load supporting portion 130 includes a mounting plate 131 on which the valve 110 is disposed and which is vertically erected; And a flange 132 extending laterally from the mounting plate 131 and fixed to the base 1 and the middle frame 3. [ In the mounting plate 131, a plurality of valves 110 are disposed. The number of the valves 110 varies depending on the water quality or the water temperature of the water discharged from the water purifier. For example, the number of the valves 110 may be increased or decreased according to the type of water provided by the water purifier, such as the mineral water and the ionized water, or the water supplied from the hot water, the cold water and the purified water.

The mounting plate 131 is equipped with a plurality of valves 110. The mounting plate 131 is connected to the flange 132. The flange 132 may be formed on the lower side and connected to the base 1, may be formed on the upper side and connected to the base 1, or may be formed on the upper side and the lower side, respectively. The flange 132 fixes the flow path switching module 100 to the base 1 and the middle frame 3. The flange 132 fixes the mounting plate 131 between the base 1 and the middle frame 3. The mounting plate 131 receives a compressive load from the base 1 and the middle frame 3. The mounting plate 131 is formed such that its longitudinal length is longer than its lateral length.

At least one of the base 1 and the middle frame 3 is formed with a cylindrical groove 133 and the flange 132 includes a cylindrical projection 134 inserted into the cylindrical groove 133. The flange 132 may be formed with a cylindrical groove 133 and the base 1 or the middle frame 3 may be formed with a cylindrical projection 134 fixed by a cylindrical groove 133. The cylindrical projection 134 may have an inner hollow cylindrical shape. The cylindrical groove 133 and the cylindrical projection 134 cooperate with each other.

At least one of the base 1 and the middle frame 3 is formed with a notch (not shown) and the flange 132 includes a fitting portion 136 to be inserted into a notch (not shown). A notch (not shown) may also be formed in the flange 132. The base 1 and / or the middle frame 3 may be formed with a fitting portion 136 to be inserted into a notch (not shown). A notch (not shown) may be formed long in the left and right direction. The fitting portion 136 may be formed long in the left-right direction. The notch (not shown) and the fitting portion 136 cooperate with each other and detachably engage with each other.

The flange 132 includes an upstanding holding portion 137 which protrudes in the horizontal direction to support the base 1 or the middle frame 3. The upstanding holding portion 137 may be formed long in the front-rear direction. The upstanding holding portion 137 may protrude toward the front of the water purifier. The upstanding holding portion 137 may be connected to the mounting portion at a right angle. The upstanding holding portion 137 may be formed so as to support the load applied by the base 1 or the middle frame 3. Due to the ribs formed in the upstanding holding portion 137, the upright holding and the flat portion may be connected in an inclined manner.

The load supporting portion 130 includes a buckling preventing rib 138 that increases the buckling load of the mounting plate 131 by wrapping the edge of the mounting plate 131. When the magnitude of the load applied by the base 1 or the middle frame 3 exceeds a predetermined value, the deformed shape changes to a shape different from that before the deformed shape, and the ability to withstand the load can be reduced. The buckling load is affected by the thickness of the section and the degree of length. The buckling load is small as the length of the mounting part is long and the cross-sectional area of the mounting part is small. The buckling prevention ribs are arranged at the rim of the mounting plate 131 to increase the buckling load. The anti-buckling rib 138 covers the rim of the mounting plate 131. The buckling prevention rib 138 protrudes toward the buckling direction of the mounting plate 131.

The load supporting portion 130 further includes a hook 139 protruding from the buckling preventing rib 138 and hooked to the valve 110. The mounting plate 131 may be partially cut. The mounting plate 131 can be cut in the shape of a hook 139. [ The hook 139 can be wrapped by the anti-buckling rib 138. A portion of the anti-buckle rib 138 may be bent into the shape of a hook 139.

The plurality of valves 110 are disposed, and the flow path switching module 100 further includes a connector 150 connecting between the plurality of valves 110 and forming flow paths in the longitudinal and transverse directions. The valve 110 is increased or decreased depending on the function of the water purifier. In the embodiment of the present invention, a total of six valves 110 are disposed on the front portion 170 and one valve 110 is disposed on the rear portion 180. However, in addition to the cold water and the purified water, 110 are further disposed. The connector 150 is connected to the plurality of valves 110. The connector 150 forms a plurality of flow paths distributed in the transverse direction. The connector 150 includes at least one flow path formed in the longitudinal direction.

The flow path switching module 100 includes a plurality of valve fixing portions 160 to which the valve 110 is fixedly mounted and the connector 150 is disposed between the valve fixing portions 160 so that both ends thereof are connected to a plurality of valves 110). The valve fixing portion 160 is formed on the mounting plate 131. A plurality of valve fixing portions 160 are formed. The valve securing portion 160 is formed on the front portion 170 and / or the rear portion 180. The valve securing portion 160 may be formed with rows longitudinally and transversely for efficient deployment. The connector 150 is disposed between the rows or columns formed by the valve fixing portion 160. [ The connector 150 is connected to the plurality of valves 110.

The valve 110 includes a switching port 111 connected to the connector 150; A connection port 113 through which the water flowing from the switching port 111 or the water flowing toward the switching port 111 flows; A switching bracket 115 disposed in the direction of the switching port 111 and fixed to the valve fixing portion 160; And a connection bracket 116 disposed in the direction of the connection port 113 and fixed to the valve fixing part 160. The valve fixing part 160 includes a pocket part 161 in which the switching bracket 115 is inserted and fixed ). The valve 110 is connected to the connector 150. The valve 110 includes a switching port 111 through which the water flows to the connector 150 or discharged from the connector 150. The valve 110 is provided with a switching port 111 and a connection port 113 at both ends thereof. A connection port 113 is formed on the opposite side of the switching port 111.

The switching port 111 is formed to open toward the connector 150. The connection port 113 is formed to open toward the opposite side of the connector 150. The valve 110 includes brackets projecting in both right and left directions. The conversion bracket 115 is protruded toward the connector 150. The connection bracket 116 is protruded toward the opposite direction of the connector 150. [ The valve fixing portion 160 is connected to the connection bracket 116 and the conversion bracket 115, respectively. The pocket portion 161 is formed in the direction of the connector 150.

The pocket portion 161 is formed with an opening portion 163 into which the conversion bracket 115 is inserted when the switching port 111 is moved in a direction to be connected to the connector 150. The pocket portion 161 is formed with an opening portion 163. The opening 163 is formed so as to face the opposite direction of the connector 150. When the switching port 111 is horizontally moved to connect the connector 150, the switching bracket 115 is inserted into the pocket portion 161. When the conversion bracket 115 is moved, the conversion bracket 115 passes through the opening portion 163 and is seated in the pocket portion 161. The pocket portion 161 accommodates the conversion bracket 115.

The valve securing portion 160 includes a support partition wall 165 for supporting the edge of the connection bracket 116. The support partition wall 165 may have a shape in which one side of the pocket portion 161 is removed. The support partition 165 is opened toward the front of the water purifier. The support partition 165 supports the lower end of the connection bracket 116. The connection bracket 116 is fixed by the support partition wall 165 and fixed to the mounting plate 131 by bolts. The support partition wall 165 is formed with a hole into which the bolt connecting the mounting plate 131 and the connection bracket 116 is inserted.

The valve 110 includes a main body 117 to which the connection port 113 and the changeover port 111 are connected; And a driving part 119 which is disposed on the upper side of the main body 117 and generates a driving force for opening and closing the flow path. The valve fixing part 160 protrudes by the step of the driving part 119 and the main part 117, 119) for fixing the fixing part (167). The driving unit 119 includes a coil that forms an electromagnetic field by an applied current. The valve 110 includes a core inserted into the upper portion of the main body 117, a coil provided outside the core, a plunger moving up and down according to an electromagnetic field formed by a current supplied to the coil, a return spring providing resilience to the plunger, And a flow blocking portion for opening and closing the flow path between the switching port 111 and the connection port 113 by linear reciprocating motion of the plunger.

When the valve 110 is normally powered on the coil, the plunger is lowered by the return spring, so that the flow path blocking portion opens the discharge hole and the fluid is discharged to the outside. When power is applied to the coil, as the plunger ascends by the electromagnetic field, the flow path blocking portion closes the discharge hole to block the discharge of the fluid to the outside. The fixing portion 167 is formed on the mounting plate 131. The fixing portion 167 protrudes. The driving unit 119 may be circular. The fixing portion 167 prevents the valve 110 from tilting due to the difference in level difference between the driving portion 119 and the main body 117. [

5 is a rear view of the channel switching module according to an embodiment of the present invention. 6 is a plan view of a valve disposed in an inclined portion according to an embodiment of the present invention.

5 to 6, the valve fixing portion 160 further includes an inclined support portion 169 that supports the valve 110 so as to protrude obliquely. The flow path switching module 100 is configured such that the connector 150 A front portion 170 disposed; A rear portion 180 on which the inclined support portion 169 is disposed; And a penetrating portion 190 that passes through the pipe connected to the connector 150 and forms a passage toward the rear portion 180. The inclined support portion 169 is formed on the rear portion 180 of the mounting portion. The inclined support portion 169 is formed obliquely toward the rear of the water purifier. The front portion 170 is provided with a connector 150 and a plurality of valves 110. The front portion 170 is disposed toward the front of the water purifier. The rear portion 180 is the opposite side of the front portion 170. The rear portion 180 is disposed toward the rear surface of the water purifier. The mounting portion forms a penetrating portion 190. The flow path connected to the connector 150 extends rearward through the penetration portion 190. The front portion 170 and the rear portion 180 are formed with a penetrating portion 190.

The angle? Of the inclined support portion 169 may be equal to the angle? Formed by the switching port 111 and the mounting plate 131. The switching port 111 is formed to be inclined with respect to the mounting plate 131. The inclined support portion 169 is formed such that the valve 110 and the mounting plate 131 are disposed to be inclined with respect to each other. The valve securing portion 160 includes a latching jaw 195 in which the connecting bracket 116 is inserted and fixed in the longitudinal direction. The catching jaw 195 can be opened toward the upper side of the water purifier. When the valve 110 is moved from the upper side to the lower side, the connection bracket 116 is inserted and fixed to the latching jaw 195. The conversion bracket 115 is disposed toward the connector 150. The conversion bracket 115 is disposed toward the penetrating portion 190. The inclined support portion 169 may be formed with a pocket portion 161. When the valve 110 is horizontally moved in the direction of the penetrating portion 190, the switching bracket 115 can be inserted into the pocket portion 161.

7 is a water pipe diagram expressing the function of the channel switching module according to an embodiment of the present invention.

Referring to FIG. 7, a water purifier according to an embodiment of the present invention includes a filter 6 for filtering raw water; A cooling pipe 92 for absorbing thermal energy from the flowing water after passing through the filter 6; And a cold water tank 93 in which the cooling pipe 92 is locked and the cold water for absorbing thermal energy is stored from the cooling pipe 92. The valve 110 prevents the purified water discharged from the filter 6 from flowing through the connector 150, A water supply valve 121 for supplying water to the water supply valve; And a cold water tank supply valve 123 for supplying purified water introduced through the connector 150 to the cold water tank 93.

The water purifier includes a heat exchanger. The heat exchanger is disposed inside the casing. The heat exchanging part includes a cooling part and / or a heating part. The refrigerator includes a compressor for compressing gaseous refrigerant by applying mechanical energy to the gaseous refrigerant, a condenser for discharging the gaseous refrigerant of high temperature and high pressure, a condenser for condensing the gaseous refrigerant, discharging the liquefied heat and discharging the liquid refrigerant of high temperature and high pressure, An expansion valve 110 for reducing the pressure of the liquid phase refrigerant to a pressure capable of evaporating and an evaporator in which the low temperature low pressure liquid phase refrigerant absorbs the heat of vaporization and changes into low temperature low pressure gaseous refrigerant.

The refrigerant flowing in the evaporator is supplied with the heat of vaporization from the purified water contained in the cold water tank (93). The purified water contained in the cold water tank 93 is cooled. The cold water tank 93 discharges cold water. A cooling pipe 92 may be formed inside the cold water tank 93. In the case of the direct water type purifier, the cold water taken by the user flows through the cooling pipe 92. The cooling pipe 92 is connected to the cold water supply valve 123. The cold water passing through the cold water supply valve 123 flows to the connector 150. The cold water having passed through the connector 150 is discharged to the main water outlet 81 through the main water outlet valve 125. The purified water at room temperature discharged from the filter 6 flows into the connector 150 through the water inlet valve 121. When the cold water supply valve 123 is opened, the purified water flowing into the connector 150 flows to the cold water tank 93. The purified water supplied to the cold water tank 93 exchanges heat with the evaporator to become cold water. The cold water stored in the cold water tank (93) exchanges heat with purified water flowing through the cooling pipe (92). When the cold water tank discharge valve 141 is opened, the cold water stored in the cold water tank 93 is discharged to the outside.

A water purifier according to an embodiment of the present invention includes a casing forming an outer shape; A filter 6 for filtering the raw water; A main water outlet portion (81) for discharging purified water and disposed outside the casing; A sub water outlet (83) for discharging the purified water and disposed separately from the main water outlet (81); And a purified water pipe 70 through which the purified water discharged from the filter 6 flows. The valve 110 is connected to the purified water pipe 70 at one side and the water inlet valve 121 ); A main water outlet valve 125 connected to the connector 150 on one side and discharging purified water on the other side to the main water outlet 81; And a sub outlet valve 126 connected to the purified water pipe 70 on one side and discharging purified water directed to the sub outlet port 83 on the other side.

The main water outlet (81) can discharge cold water, purified water, hot water, and the like. The sub water outlet portion 83 is formed separately from the main water outlet portion 81. The sub water outlet portion 83 can be used to supply purified water directly to a large-diameter pot, a cooking utensil, or the like. For example, the sub water outlet portion 83 may be formed to be rotatable or have a larger radius of rotation. The sub water outlet portion 83 can be separated from the casing by the main water outlet portion 81 to discharge the purified water.

The sub water outlet portion 83 may discharge purified water, hot water or cold water, but only the purified water may be discharged in the embodiment. In this case, the sub outlet valve 126 is formed separately from the main outlet valve 125. Further, the sub-outlet valve 126 is not connected to the connector 150. This is because at least two valves 110 must be driven to discharge the purified water to the sub water outlet 83 when the sub water outlet valve 126 and the connector 150 are connected. Therefore, the sub-outlet valve 126 is directly supplied with the purified water discharged from the filter 6.

The water purifier according to an embodiment of the present invention includes a filter 6 for filtering raw water; A purified water pipe (70) through which purified water discharged from the filter (6) flows; And a hot water tank 91 in which the purified water discharged from the purified water pipe 70 forms a space for absorbing thermal energy. The valve 110 is connected to the purified water pipe 70 on one side, A hot water supply valve 124 for discharging the purified water toward the hot water supply valve 91; And a hot water inlet valve 122 connected to the connector 150 at the other side, hot water discharged from the hot water tank 91 is received. The heating section includes a resistance wire to which a current is applied and which generates joule heat, and a hot water tank 91 that absorbs the joule heat from the resistance wire.

The purified water contained in the hot water tank 91 absorbs thermal energy from the hot water tank 91 and is heated. The hot water tank 91 discharges hot water. The hot water tank 91 accommodates a constant temperature at room temperature. The constant absorbs heat energy in the hot water tank 91. The hot water tank 91 discharges hot water. The hot water supply valve 124 is supplied with purified water through the filter 6. When the hot water supply valve 124 opens the flow path, the purified water flows to the hot water tank 91. When the steam valve 143 is opened, the steam formed in the hot water tank 91 flows into the cold water pipe. The steam flowing into the cold water pipe sterilizes and cleans the cold water pipe. When the hot water inlet valve 122 is opened, the hot water contained in the hot water tank 91 flows to the connector 150. When the main water outlet valve (125) opens the flow path, hot water is discharged to the main water outlet (81).

The water purifier according to one embodiment of the present invention includes a connector 150 having a valve connection part 153 protruding laterally and connected to the valve 110; And piping connection portions 151 and 155 protruding in the longitudinal direction and connected to the piping. The piping connection portions 151 and 155 are formed on the upper side and include a cold water receiving portion 151 that receives cold water. And a residual liquid flow portion 155 formed by the self-weight of the water contained therein is formed. The connector 150 is disposed on the mounting plate 131 in the longitudinal direction. The connector 150 forms a flow path in the lateral direction and the longitudinal direction. The valve connection portion 153 extends in the transverse direction and is connected to the valve 110. The valve connection portion 153 is connected to the switching port 111.

The pipe connection portions 151 and 155 are elongated in the longitudinal direction. The pipe connection portions 151 and 155 are formed with a cold water receiving portion 151 on the upper side. The pipe connecting portions 151 and 155 are formed with a residual flow portion 155 on the lower side. The cold water receiving portion 151 is connected to the cold water pipe. The residual fluid flow section 155 is connected to the discharge valve 127. The flow path connecting the residual fluid flow section 155 and the discharge valve 127 passes through the penetration section 190.

The water purifier according to an embodiment of the present invention further includes a discharge valve 127 for discharging the purified water supplied through the residual fluid flow unit 155, (170); And a rear portion 180 on which the discharge valve 127 is mounted and a pipe connecting the residual flow portion 155 and the discharge valve 127 passes through the front portion 170 and the rear portion 180. The mounting plate 131 may include a front portion 170 and a rear portion 180. The pipe connecting the residual fluid feeding section 155 and the discharge valve 127 passes through the mounting plate 131. The water contained in the connector 150 is held in the lower side by its own weight. The residual fluid feeding part 155 is formed on the lower side of the connector 150. When the discharge valve 127 is opened, water is discharged through the residual flow-through portion 155.

A water purifier according to an embodiment of the present invention includes a casing forming an outer shape; And a main water outlet (81) disposed outside the casing for supplying purified water and a purified water to the main water outlet (81). The valve (110) (125), and the main water outlet valve (125) opens the flow path when the discharge valve (127) is opened. The residual water stored in the connector 150 can be maintained in a vacuum state even when the discharge valve 127 is opened. In this case, the air pressure inside the connector 150 is lower than the atmospheric pressure, so that the residual water may not be discharged. Therefore, when the discharge valve 127 is opened, the main outlet valve 125 can be opened.

When the main water outlet valve 125 is opened, the air pressure inside the connector 150 becomes equal to the atmospheric pressure, so that the remaining water flows to the discharge valve 127. The operation of the water purifier according to the present invention will now be described. In the middle frame 3, a plurality of filters 6, a water reservoir 7, and the like are disposed, and the plurality of filters 6 and the water reservoir 7 are filled with water. Further, the middle frame 3 is disposed apart from the base 1 for forming a lower space. The load exerted from the middle frame 3 and the base 1 is supported by the load supporting portion 130. The load support 130 is formed with a flange 132 to maintain its upright position. The flange 132 firmly fixes the load supporting portion 130 to the base 1 and the middle frame 3. Thus, the vibration is reduced and the vibration stress, which adversely affects the support structure, is reduced.

 In addition, since the buckling prevention rib 138 protrudes laterally from the rim of the mounting plate 131, the buckling load is increased. Therefore, the volume of the water purifier is reduced, and the internal space of the casing is widened, since no separate flat frame is required. Further, the hook 139 can be integrally formed to fix the electric wire or the flow path, so that the internal structure can be formed concurrently during assembly.

A connector 150 is disposed between the plurality of valves 110. The connector 150 is centrally located and the valve 110 is inserted laterally toward the connector 150. The pocket portion 161 forms an opening portion 163 and the opening portion 163 is opened toward the switching bracket 115. Therefore, the operation of inserting the valve 110 into the connector 150 and the operation of inserting the switching bracket 115 into the pocket portion 161 can be performed at the same time during assembling, simplifying the process. In addition, since a plurality of valve 110 mounting portions capable of mounting a plurality of valves 110 are formed, the flow path switching module 100 can be used in a water purifier having various functions. This is because the valve 110 can be increased as the function increases.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It should be understood that various modifications may be made by those skilled in the art without departing from the spirit and scope of the present invention.

Claims (23)

A base defining a bottom surface;
A middle frame disposed above the base; And
And a flow path switching module disposed between the base and the middle frame to support a load applied from the middle frame and to control a flow path by mounting a plurality of valves. The method according to claim 1,
The channel switching module includes:
Further comprising a load bearing mounted on the valve and erected between the middle frame and the base. 3. The method of claim 2,
The load-
A mounting plate on which the valve is disposed and erected in a vertical direction; And
And a flange extending laterally from the mounting plate and fixed to the base and the middle frame. The method of claim 3,
At least one of the base and the middle frame is formed with a cylindrical groove,
Wherein the flange comprises:
And a cylindrical projection inserted into the cylindrical groove. The method of claim 3,
At least one of the base and the middle frame is formed with a notch,
Wherein the flange comprises:
And a fitting portion to be inserted into the notch. The method of claim 3,
Wherein the flange comprises:
And an upright holding part protruding in a horizontal direction to support the base or the middle frame. The method of claim 3,
The load-
And a buckling prevention rib which surrounds an edge of the mounting plate to increase a buckling load of the mounting plate.
8. The method of claim 7,
The load-
And a hook protruding from the buckling preventing rib to hook an electric wire connected to the valve. 3. The method of claim 2,
Wherein the plurality of valves are arranged,
The channel switching module includes:
Further comprising a connector connecting the plurality of valves and forming a flow path in the longitudinal and transverse directions. 10. The method of claim 9,
The channel switching module includes:
A plurality of valve fixing portions to which the valves are fixedly mounted,
Wherein the connector is disposed between the valve fixing portions and has both ends connected to the plurality of valves. 11. The method of claim 10,
Wherein the valve comprises:
A switching port connected to the connector;
A connection port through which water flowing from the switching port or water flowing toward the switching port flows;
A switching bracket disposed in the direction of the switching port and fixed to the valve fixing portion; And
And a connection bracket disposed in the connection port direction and fixed to the valve fixing portion,
Wherein the valve-
And a pouch portion to which the conversion bracket is inserted and fixed. 12. The method of claim 11,
The pod portion
And an opening through which the conversion bracket is inserted is formed when the switching port is moved in a direction connecting the connector. 12. The method of claim 11,
Wherein the valve-
And a support partition wall for supporting an edge of the connection bracket. 12. The method of claim 11,
Wherein the valve comprises:
A main body to which the connection port and the switching port are connected; And
And a driving unit disposed on the upper side of the main body to generate a driving force for opening and closing the flow path,
Wherein the valve-
Further comprising a fixing part protruding by a step between the driving part and the main body to fix the driving part. 12. The method of claim 11,
Wherein the valve-
Further comprising an inclined portion projecting obliquely to support the valve,
The channel switching module includes:
A front portion on which the connector is disposed;
A rear portion on which the inclined support portion is disposed; And
And a through-hole penetrating the pipe connected to the connector and forming a passage toward the rear portion. 16. The method of claim 15,
The angle of the inclined support portion
And an angle formed between the switching port and the mounting plate. 16. The method of claim 15,
Wherein the valve-
And a coupling jaw (22) in which the connection bracket (22) is inserted and fixed in the longitudinal direction. 10. The method of claim 9,
A filter for filtering raw water;
A cooling piping for absorbing thermal energy from the flowing water after passing through the filter; And
And a cold water tank in which the cooling pipe is locked and cold water for absorbing thermal energy from the cooling pipe is stored,
Wherein the valve comprises:
A water purifying valve for supplying purified water discharged from the filter to the connector; And
And a cold water tank supply valve for supplying purified water introduced through the connector to the cold water tank. 10. The method of claim 9,
A casing forming an outer shape;
A filter for filtering raw water;
A main water outlet which is disposed outside the casing and in which purified water is discharged;
Wherein the purified water is discharged and disposed separately from the main water outlet
A sub-heading section; And
And a purified water pipe through which the purified water discharged from the filter flows,
Wherein the valve comprises:
A water inlet valve connected at one end to the purified water pipe and at the other end to the connector;
A main water outlet valve connected to the connector on one side and discharging purified water toward the main water outlet on the other side; And
And a sub outlet valve connected to the purified water pipe on one side and discharging purified water on the other side toward the sub outlet. 10. The method of claim 9,
A filter for filtering raw water;
A purified water pipe through which the purified water discharged from the filter flows; And
Wherein the purified water discharged from the purified water pipe forms a space for absorbing thermal energy,
Wherein the valve comprises:
A hot water supply valve connected at one side to the purified water pipe and at the other side to discharge purified water toward the hot water bath; And
Wherein one side of the water purifier includes hot water discharged from the hot water tank and the other side includes a hot water inlet valve connected to the connector. 10. The method of claim 9,
Wherein the connector comprises:
A valve connecting portion protruding in a lateral direction and connected to the valve; And
And a pipe connecting portion protruding in the longitudinal direction and connected to the pipe,
Wherein the pipe connection portion comprises:
A cold water receiving portion formed on the upper side and obtained by the cold water; And
And a residual water flow portion formed on the lower side and flowing by the self weight of the water contained in the water purifier. 22. The method of claim 21,
Further comprising a discharge valve for discharging the purified water supplied through the residual fluid supplying section,
The channel switching module includes:
A front portion on which the connector is disposed; And
And a rear portion on which the discharge valve is mounted,
And a pipe connecting the residual fluid flow portion and the discharge valve passes through the front portion and the rear portion. 22. The method of claim 21,
A casing forming an outer shape; And
Further comprising a main take-out part which supplies purified water and is disposed outside the casing,
Wherein the valve comprises:
And a main water outlet valve for discharging purified water supplied from the connector toward the main water outlet,
Wherein the main water outlet valve comprises:
And opens the flow path when the discharge valve is opened.

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