JP7130270B2 - Water discharge head with water purification function, water purification cartridge and faucet device - Google Patents

Description

TECHNICAL FIELD The present invention relates to a water discharge head with a water purification function, a water purification cartridge, and a faucet device.

Japanese Patent No. 6186059 discloses a water purifier cartridge that is exchangeably housed in a water purifier housing. This water purifier cartridge has a buffer portion that is arranged downstream of the purification material and blocks water hammer from the flow path switching valve to the purification material.

Japanese Patent No. 6186059

The technique disclosed in Japanese Patent No. 6186059 is effective in preventing breakage of the purification material. The technique disclosed in Japanese Patent No. 6186059 is effective in preventing sticking between a water purifier and a water purifier cartridge.

Based on the new point of view, the inventors have found room for improvement. The present disclosure provides an improved spouting head, purification cartridge and faucet.

In one aspect, the water purification cartridge is arranged in the water purification cartridge mounting portion of the water discharge head with water purification function, and has a connecting end connected to the connection receiving portion of the water purification cartridge mounting portion. The connection end has a purified water outlet hole, a first annular packing positioned downstream from the purified water outlet hole, and a second annular packing positioned upstream from the purified water outlet hole. The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing.

In another aspect, the water discharge head with a water purification function includes a discharge port, a raw water flow path, a purified water flow path, a switching mechanism for switching between the raw water flow path and the purified water flow path, and It has a water purification cartridge for generating purified water, and a water purification cartridge mounting portion in which the water purification cartridge is arranged. The water purification cartridge mounting portion has a connection receiving portion that connects with the water purification cartridge. The water purification cartridge has a connection end connected to the connection receptacle. The connection end has a purified water outlet hole, a first annular packing positioned downstream from the purified water outlet hole, and a second annular packing positioned upstream from the purified water outlet hole. The outer diameter of the first annular packing is smaller than the outer diameter of the second annular packing.

Another aspect is a faucet device provided with the water discharge head with the water purification function.

Based on the novel structure, improved spouting heads, water purification cartridges and faucets are obtained.

FIG. 1 is a perspective view of a faucet device according to one embodiment. 2 is a front view of a water discharge head in the faucet device of FIG. 1. FIG. 3(a) and 3(b) are cross-sectional views taken along line AA in FIG. The phase of the water purification cartridge is different between FIG. 3(a) and FIG. 3(b). 4(a) is a sectional view taken along line aa in FIG. 4(b), and FIG. 4(b) is a sectional view taken along line bb in FIG. 4(a). 5(a) is a sectional view taken along line aa in FIG. 5(b), and FIG. 5(b) is a sectional view taken along line bb in FIG. 5(a). 6 is a perspective view of a water purification cartridge attached to the faucet device of FIG. 1. FIG. FIG. 7(a) is a side view of the water purification cartridge of FIG. 6, FIG. 7(b) is a front view of the water purification cartridge as seen from the front (downstream side), and FIG. 7(b) is a cross-sectional view taken along line cc, and FIG. 7(d) is a cross-sectional view taken along line dd of FIG. 7(b). FIG. 8 is a partially enlarged view of FIG. 7(c). FIG. 9 is a partially enlarged view of FIG. 7(d). FIG. 10 is a partially enlarged view of FIG. 3(b). FIG. 11 is a partially enlarged view of FIG. 5(b). 12 is a partially enlarged view of FIG. 11. FIG. FIG. 13 is a partially enlarged view of FIG. 2 of Japanese Patent No. 6186059. FIG.

Hereinafter, embodiments will be described in detail with reference to the drawings as appropriate.

In addition, unless otherwise specified, the radial direction in the present application means the radial direction of the water purification cartridge attached at the regular position. Unless otherwise specified, the axial direction in this application means the axial direction of the water purification cartridge installed in the normal position.

Unless otherwise specified, the upstream side in this application means the upstream side in the flow of water, and the downstream side means the downstream side in the flow of water. Further, in the water purification cartridge, the upstream side and the downstream side are determined based on the axial direction. That is, in the water purification cartridge, the axial front end side is the downstream side, and the axial rear end side is the upstream side. The downstream side is also referred to as the front side, and the upstream side is also referred to as the rear side, unless otherwise specified.

[Knowledge on which the present disclosure is based]
FIG. 13 is a partially enlarged view of FIG. 2 of Japanese Patent No. 6186059. FIG. In this embodiment, two O-rings 13 are arranged on the outer peripheral surface of the connecting tube portion 10a of the water purifier cartridge. The outer diameter of the downstream O-ring 13a is equal to the outer diameter of the upstream O-ring 13b. The outlet 10 e is positioned to match the purified water receiving opening 11 a of the cartridge receiver 11 . The outlet 10e extends radially.

When the water purification cartridge is attached, the connection tube portion 10a is inserted into the cartridge receiver 11. As shown in FIG. During this insertion, the downstream O-ring 13 a is rubbed against the first edge 15 and then against the second edge 16 . In other words, it is rubbed twice with one insertion. Therefore, the O-ring 13a on the downstream side is likely to be damaged (improvement object 1).

At the initial stage of insertion, only the O-ring 13a on the downstream side is inserted inside the cartridge receptacle 11, and the O-ring 13b on the upstream side is not inserted inside the cartridge receptacle 11. As shown in FIG. In this state, the center line z1 of the water purification cartridge tends to be inclined with respect to the cartridge receiver 11. As shown in FIG. Due to this inclination, the radial ends 17 and 18 of the wall portions located on both sides of the O-ring 13 a on the downstream side come into contact with the inner surface of the cartridge receiver 11 . Since the connecting tube portion 10a is inserted into the cartridge receiver 11 while generating this contact, the inner surface of the cartridge receiver 11 is easily damaged (improvement object 2).

Inclining the outlet 10e with respect to the radial direction while securing the cross-sectional area of the outlet 10e increases the axial length of the peripheral portion of the outlet 10e. This increase in axial length tends to lengthen the overall length of the water purification cartridge or sacrifice the water purification performance (the length of the water purification material). On the other hand, when the outlet 10e extends in the radial direction, the purified water discharged radially outward hits the surface of the flow path forming member substantially perpendicularly and then flows downstream (see the arrow in FIG. 13). reference). In this case, the flow path resistance tends to increase (improvement target 3).

In the gap 19 between the radial tip 17 of the wall located upstream of the downstream O-ring 13a and the opposing member, water scale, dirt, etc. can accumulate. When the water purification cartridge is removed, this deposit may be scraped out by the O-ring 13a on the downstream side and enter the water purification channel from the water purification receiving port 11a (improvement target 4).

The following embodiments can improve the above-mentioned newly found improvement targets.

[First embodiment]
FIG. 1 is a perspective view of a faucet device 102 according to one embodiment. The faucet device 102 is attached to a sink (not shown). In FIG. 1, the description of the parts that are not visible, that is, the parts that are inside the sink are omitted. In addition to the sink, a washbasin and a bathroom are exemplified as an installation place of the faucet device 102 .

The faucet device 102 has a main body 104, a lever handle 106, and a water discharge head 108 with a water purification function. The faucet device 102 is a so-called single-lever faucet. The temperature of the spouted water can be adjusted by turning the lever handle 106 left and right. The amount of spouted water can be adjusted by rotating the lever handle 106 up and down. A valve mechanism that enables adjustment of the temperature and amount of spouted water is built in the body portion 104 . This valve mechanism is known.

Although not shown, the faucet fixture having the faucet device 102 has a hot water introduction pipe and a water introduction pipe. The hot water introduction pipe is connected to, for example, a pipe extending from the water heater. The water introduction pipe is connected, for example, to a water supply pipe without passing through a water heater.

Heated hot water is introduced into the hot water introduction pipe. Heating is provided by a water heater. Unheated water is introduced into the water introduction pipe. The valve mechanism adjusts the mixing ratio of hot and cold water. This mixing ratio achieves temperature control of the jet water. In the following description, heated hot water, unheated water, and a mixed liquid thereof are also simply referred to as "water."

The water discharge head 108 has a water guide section 110 , a switching section 112 , an operation section 114 , a water shape adjustment section 116 , a display section 120 and a discharge port 122 . In this embodiment, the operation unit 114 is a push button. The water guide part 110 also functions as a grip part.

The water shape adjustment unit 116 can change the shape (water shape) of water to be discharged. The water shape adjusting section 116 has a water shape adjusting lever 118 . The water shape can be changed by operating the water shape adjustment lever 118 . Two or more water shapes can be selected by operating the water shape adjusting lever 118 . In the case of a configuration in which two types of water shapes can be selected, it is preferable to allow selection of the straight water shape and the shower water shape. In the case of a configuration in which three types of water shapes can be selected, it is preferable to select a straight water shape and a first shower water shape and a second shower water shape with different shower water discharge modes. configuration is adopted. The shower water discharge mode includes the shower water discharge range, the shower water discharge amount, the force of the shower water discharge, and the like.

The water discharge head 108 has a raw water channel and a purified water channel. When the raw water flow path is selected, raw water is discharged from the discharge port 122 . A state in which raw water is discharged is also referred to as a raw water discharge state. When the purified water flow path is selected, purified water is discharged from the discharge port 122 . A state in which purified water is discharged is also referred to as a purified water discharge state.

The switching unit 112 has a switching mechanism capable of switching between purified water and raw water by operating the operation unit 114 . With this switching mechanism, either the raw water discharge state or the purified water discharge state can be selected.

FIG. 2 is a front view of the water discharge head 108. FIG. 3(a) and 3(b) are cross-sectional views taken along line AA in FIG. The difference between FIG. 3(a) and FIG. 3(b) is the circumferential position (phase) of the water purification cartridge. 3(a) and 3(b), the operating portion 114 is in the extended position. 4(a), 4(b), 5(a) and 5(b) are also sectional views of the water discharge head 108. FIG. FIG. 4(a) is a cross-sectional view taken along line aa in FIG. 4(b). FIG. 4(b) is a cross-sectional view taken along line bb in FIG. 4(a). 4(a) and 4(b), the operating portion 114 is in the extended position. FIG. 5(a) is a cross-sectional view taken along line aa in FIG. 5(b). FIG. 5(b) is a cross-sectional view taken along line bb in FIG. 5(a). 5(a) and 5(b), the operating portion 114 is in the pushed position. In addition, in FIGS. 4(a), 4(b), 5(a), and 5(b), the line visible in the background of the cross section is omitted.

Operation unit 114 functions as a switching button. When switching the flow path, the operation part 114 is pressed. Every time the operation part 114 is pressed, switching between the raw water channel and the purified water channel is performed. In other words, each time the operating portion 114 is pressed, switching between the raw water discharge state and the purified water discharge state is performed. The switching mechanism has an alternate operation type thrust lock mechanism. This thrust lock implements the push button operation of the operation unit 114 . Each time the push button 114 is pushed, the push button 114 transitions between the extended position and the pushed position. This switching mechanism is known.

In this embodiment, raw water is discharged when the push button 114 is at the protruded position, and purified water is discharged when the push button 114 is at the pushed position. Therefore, FIGS. 3(a), 3(b), 4(a) and 4(b) show raw water discharge states, and FIGS. 5(a) and 5(b) show purified water discharge states. Conversely, purified water may be dispensed when the push button 114 is in the extended position, and raw water may be dispensed when the push button 114 is in the depressed position.

The water discharge head 108 has a water purification cartridge PC1. The water purification cartridge PC1 is arranged inside the water guide section 110 . The water guide section 110 has an outer cylindrical section 124 . A water purification cartridge PC1 is arranged inside the outer cylindrical portion 124 .

A raw water flow path WG is formed outside the water purification cartridge PC1. A water purification channel WJ is formed inside the water purification cartridge PC1. In the raw water discharge state, raw water that has passed through the raw water flow path WG is discharged from the discharge port 122 via the raw water flow path WG in the switching mechanism. On the other hand, in the purified water discharge state, the raw water is filtered through the permeable portion 126 of the water purification cartridge PC1 in the process from the outside to the inside of the water purification cartridge PC1 and becomes purified water. Purified water is discharged from the discharge port 122 via the purified water flow path WJ inside the water purification cartridge PC1 and the purified water flow path WJ in the switching mechanism. In addition, this permeation|transmission part 126 is an example of a water purification function part.

The switching portion 112 of the water discharge head 108 has a first valve 130 and a second valve 132 . Water discharge is switched by opening and closing the two valves.

As shown in FIG. 4B, the first valve 130 has a valve seat 130a, a first valve body 130b, a ball holder 130c, and an elastic body 130d. The first valve 130 is a ball valve. The first valve body 130b is a ball. The valve seat 130a is the opening edge of a circular hole. Ball 130b is held by ball holder 130c. The ball holder 130c is open downward. An elastic body 130d is arranged between the upper portion of the ball holder 130c and the ball 130b. This elastic body 130d is a coil spring. The ball 130b is always urged toward the valve seat 130a by the elastic body 130d.

As shown in FIG. 5B, the second valve 132 has a valve seat 132a, a second valve body 132b, a ball holder 132c, and an elastic body 132d. The second valve 132 is a ball valve. The second valve body 132b is a ball. The valve seat 132a is the opening edge of the circular hole. The ball 132b is held by a ball holder 132c. The ball holder 132c is open downward. An elastic body 132d is arranged between the upper part of the ball holder 132c and the ball 132b. This elastic body 132d is a coil spring. The ball 132b is always urged toward the valve seat 132a by the elastic body 132d.

The push button 114 is connected to the ball holders 130c and 132c via the thrust lock mechanism. Ball retainer 130 c and ball retainer 132 c move together with push button 114 . Ball 130b moves with ball retainer 130c, and ball 132b moves with ball retainer 132c. The valve seats 130a and 132a are aligned in a direction substantially perpendicular to the direction of movement of the push button 114, but their positions are (slightly) different in the direction of movement.

4(a) and 4(b), when the operating portion 114 is in the protruding position, the ball 132b is fitted into the valve seat 132a, and the second valve 132 is closed. At this time, the center of the ball 130b is displaced from the center of the valve seat 130a, and the first valve 130 is open. In this state, raw water is discharged. The second valve 132 is a clean water cutoff valve that closes the clean water flow path.

5(a) and 5(b), when the operating portion 114 is in the pushed position, the ball 130b is fitted into the valve seat 130a and the first valve 130 is closed. At this time, the center of the ball 132b is displaced from the center of the valve seat 132a, and the second valve 132 is open. In this state, purified water is discharged. The first valve 130 is a raw water cutoff valve that closes the raw water flow path.

The water discharge head 108 has a water purification cartridge mounting portion 134 . The water purification cartridge mounting portion 134 has a cylindrical hollow portion 136 in which an intermediate portion of the water purification cartridge PC1 is arranged, and a connection receiving portion 138 . Cylindrical hollow portion 136 is formed inside outer cylindrical portion 124 . The connection receiver 138 is located downstream of the cylindrical cavity 136 .

FIG. 6 is a perspective view of the water purification cartridge PC1. 7(a) is a side view of the water purification cartridge PC1, FIG. 7(b) is a front view of the water purification cartridge PC1, and FIG. 7(c) is a cross section taken along line cc in FIG. 7(b). 7(d) is a cross-sectional view taken along line dd in FIG. 7(b).

The water purification cartridge PC1 has an intermediate portion 150 , a connection end portion 152 arranged at the front end portion of the intermediate portion 150 , and a rear forming portion 154 arranged at the rear end portion of the intermediate portion 150 . The connecting end 152 is coaxial with the intermediate portion 150 . The posterior forming portion 154 is coaxial with the intermediate portion 150 .

The connecting end portion 152 is provided downstream of the intermediate portion 150 . The interior of the connection end portion 152 is hollow. This cavity functions as a purified water flow path WJ. That is, the connecting end portion 152 has the purified water flow path WJ therein. The material of the connection end portion 152 is resin. The connecting end 152 is integral as a whole. The connecting end portion 152 is integrally molded with resin. The connecting end portion 152 may be formed by combining a plurality of separately molded members.

Middle portion 150 is cylindrical. The intermediate portion 150 has a permeable portion 151 through which water can pass. The intermediate portion 150 has a filtering function. Intermediate portion 150 has a hollow portion therein. This hollow portion functions as a purified water flow path WJ. The intermediate section 150 may have, for example, an outer filtration layer and an inner filtration layer. A water purification material may be arranged between the outer filter layer and the inner filter layer. The water purification material contains, for example, activated carbon as a main component. For example, a nonwoven fabric is used for the outer filter layer and the inner filter layer. A sterilizing ceramic may be employed for the outer and/or inner filtration layer. Ion exchangers may be employed in the outer filtration layer and/or the inner filtration layer. The outer filtration layer may be multiple layers. The inner filtration layer may be multiple layers. Note that the intermediate portion 150 of the present embodiment is an example of a water purification function portion (a portion that exhibits a water purification function). The intermediate portion 150 may not have a filtering function. The intermediate portion 150 may be a cylindrical wall that is impermeable to water.

The water purification cartridge PC1 of this embodiment has a purification material capable of removing chlorine. Activated carbon is exemplified as this purification material.

The rear forming portion 154 closes the rear side of the intermediate portion 150 . On the other hand, the connection end 152 is water permeable. The internal space of the connecting end portion 152 is the purified water flow path WJ. Purified water generated by passing through the intermediate portion 150 passes through the connecting end portion 152 and reaches the switching portion 112 .

In addition, the rear forming portion 154 may be made water-permeable. For example, raw water may flow into the intermediate portion 150 through a through hole provided in the rear formation portion 154 of the water purification cartridge PC1. In this case, the intermediate portion 150 may be a non-permeable cylindrical wall portion.

The connecting end 152 has a first cylindrical portion 160 . Additionally, the connecting end 152 has a second cylindrical portion 162 . Additionally, the connecting end 152 has a third cylindrical portion 164 . Additionally, the connecting end 152 has a retaining barrel 166 . The first cylindrical portion 160 is positioned downstream of the second cylindrical portion 162 . The second cylindrical portion 162 is positioned downstream of the third cylindrical portion 164 . The third cylindrical portion 164 is located downstream of the holding cylindrical portion 166 . The second cylindrical portion 162 is located between the first cylindrical portion 160 and the third cylindrical portion 164 . The first cylindrical portion 160 and the second cylindrical portion 162 are coaxial. The second cylindrical portion 162 and the third cylindrical portion 164 are coaxial. The third cylindrical portion 164 and the holding cylindrical portion 166 are coaxial. The centerline of the first cylindrical portion 160 coincides with the centerline z1 of the water purification cartridge PC1. The centerline of the second cylindrical portion 162 coincides with the centerline z1 of the water purification cartridge PC1. The centerline of the third cylindrical portion 164 coincides with the centerline z1 of the water purification cartridge PC1. The centerline of the holding cylindrical portion 166 coincides with the centerline z1 of the water purification cartridge PC1.

The connecting end portion 152 has a first annular packing s1 and a second annular packing s2. In this embodiment, the first annular packing s1 is an O-ring. In this embodiment, the second annular packing s2 is an O-ring.

The connecting end 152 has a maximum outer diameter. In this embodiment, the largest outer diameter of connecting end 152 is retaining cylinder 166 . This maximum outer diameter portion (holding cylindrical portion 166 ) covers the downstream end of intermediate portion 150 . This maximum outer diameter portion (holding cylindrical portion 166 ) holds the downstream end of intermediate portion 150 .

The outer diameter of the first cylindrical portion 160 is smaller than the outer diameter of the second cylindrical portion 162 . The outer diameter of the second cylindrical portion 162 is smaller than the outer diameter of the third cylindrical portion 164 . The outer diameter of the third cylindrical portion 164 is smaller than the outer diameter of the holding cylindrical portion 166 .

The connecting end portion 152 has a first annular packing s1 and a second annular packing s2. The first annular packing s1 is arranged on the first cylindrical portion 160 . The second annular packing s2 is arranged on the second cylindrical portion 162 .

FIG. 8 is a partially enlarged view of FIG. 7(c). FIG. 9 is a partially enlarged view of FIG. 7(d).

The first cylindrical portion 160 constitutes the downstream end portion of the connecting end portion 152 . The first cylindrical portion 160 constitutes the downstream end of the water purification cartridge PC1.

The first cylindrical portion 160 constitutes the downstream end of the water purification cartridge PC1. The first cylindrical portion 160 constitutes the downstream end portion of the connecting end portion 152 .

The connecting end 152 has a tip 170 . In this embodiment, the first cylindrical portion 160 is the tip portion 170 . The tip 170 has a first groove 172 . The first groove 172 is formed on the outer peripheral surface of the distal end portion 170 (first cylindrical portion 160). The first groove 172 is a circumferential groove. The first groove 172 is formed between the front wall portion 173a and the rear wall portion 173b. The front wall portion 173 a forms a front side surface of the first groove 172 . The rear wall portion 173 b forms a rear side surface of the first groove 172 .

The first annular packing s1 is arranged at the distal end portion 170 . The first annular packing s1 is arranged in the first groove 172. As shown in FIG.

The tip 170 has a tip surface 174 . The tip surface 174 is the tip surface of the water purification cartridge PC1. The distal end surface 174 is the distal end surface of the connecting end portion 152 . The tip surface 174 is flat. The tip surface 174 extends radially. The tip surface 174 is annular (see FIG. 7(b)). The tip surface 174 is provided over the entire circumferential direction. The center of the tip surface 174 is positioned on the center line z1 of the water purification cartridge PC1.

Tip 170 is impermeable to water. The inner surface of the tip portion 170 faces the purified water flow path WJ. In this embodiment, the inner surface of tip 170 includes inner surface 194, which is described below. The outer surface of the tip portion 170 faces the raw water flow path WG. In this embodiment, the outer surface of tip 170 includes tip surface 174 and recess 176 . The outer surface of tip 170 has a recess 176 . The inner surface and the outer surface of the tip portion 170 are partitioned by a first annular packing s1. The centerline of the tip portion 170 coincides with the centerline z1 of the water purification cartridge PC1. The tip portion 170 is arranged at a position that intersects the center line z1 of the water purification cartridge PC1.

The recess 176 is open downstream. The recess 176 is open axially forward. The recess 176 is open to the raw water flow path WG. The recess 176 is impermeable to water. The cross-sectional shape of the recess 176 is circular (see FIG. 7B). A tip surface 174 is arranged around the recess 176 (outside in the radial direction). Recess 176 forms a cavity inside tip 170 . The recess 176 forms a cylindrical cavity. The cavity formed by the recess 176 exists radially inside the first annular packing s1. A cavity formed by the recess 176 exists radially inside the first groove 172 . The centerline of the tip surface 174 coincides with the centerline z1 of the water purification cartridge PC1.

As shown in FIGS. 8 and 9, recess 176 has side surfaces 178 and bottom surface 180 . Side 178 is a circumferential surface. The side surface 178 is located radially inside the first groove 172 . The bottom surface 180 is planar. The bottom surface 180 extends radially. The bottom surface 180 is circular. The center of the bottom surface 180 is positioned on the center line z1 of the water purification cartridge PC1.

A cavity is formed by a concave portion 176 inside the first groove 172 in the radial direction. A cavity is formed by a recess 176 on the radially inner side of the bottom surface 172a.

The tip portion 170 has a partition wall 190 . Partition wall 190 is impermeable to water. The partition wall 190 is located upstream of the tip surface 174 . The partition wall 190 extends radially. The centerline of the partition wall 190 coincides with the centerline z1 of the water purification cartridge PC1.

The partition wall 190 crosses the center line z1 of the water purification cartridge PC1. That is, the partition wall 190 is provided at a position intersecting the center line z1 of the water purification cartridge PC1. In this embodiment, the partition wall 190 intersects the center line z1 of the water purification cartridge PC1 at its center. The partition wall 190 may intersect the center line z1 of the water purification cartridge PC1 at a position other than its center. Partition wall 190 constitutes bottom surface 180 of recess 176 . The bottom surface 180 is the outer surface 192 of the partition wall 190 . Thus, the outer surface of the tip portion 170 has a recess 176 whose bottom surface 180 is the outer surface 192 of the partition wall 190 .

The partition wall 190 separates the inside and outside of the water purification cartridge PC1. An outer surface 192 of the partition wall 190 constitutes an outer surface of the water purification cartridge PC1. The outer surface 192 faces the raw water flow path WG. An inner surface 194 of the partition wall 190 constitutes an inner surface of the water purification cartridge PC1. The inner surface 194 faces the purified water flow path WJ.

The connection end 152 has a coupling extension 200 . The connecting extension 200 connects the first cylindrical portion 160 and the second cylindrical portion 162 . As shown in FIGS. 6 and 7B, a plurality of connecting extensions 200 are arranged at regular intervals in the circumferential direction. In this embodiment, four connecting extensions 200 are arranged at equal intervals in the circumferential direction. The connecting extension part 200 extends in a direction inclined with respect to the center line z1 of the water purification cartridge PC1. The connecting extension portion 200 extends radially inward toward the downstream side. The connecting extension portion 200 connects the downstream side of the second cylindrical portion 162 and the upstream side of the first cylindrical portion 160 .

The second cylindrical portion 162 has a second groove 210 . The second groove 210 is a circumferential groove. The second groove 210 is formed on the outer peripheral surface of the second cylindrical portion 162 . A second annular packing s2 is arranged in the second groove 210 . The inside of the second cylindrical portion 162 is hollow. The inside of the second cylindrical portion 162 is the purified water flow path WJ.

The second cylindrical portion 162 has a downstream end face 212 . The downstream end face 212 is flat. The downstream end face 212 extends radially. The downstream end face 212 is annular. The downstream end face 212 is formed over the entire circumferential direction.

The downstream end face 212 may be continuously formed in the entire circumferential direction. The downstream end face 212 may be formed by arranging the partitioned portions partitioned by the connecting extension portion 200 in the circumferential direction. The downstream end face 212 may have a portion continuously formed in the entire circumferential direction and a portion in which the partitioned portions partitioned by the connecting extension portions 200 are arranged in the circumferential direction. In this embodiment, the downstream end face 212 is formed by arranging four partitioned portions 214 partitioned by the connecting extension portion 200 in the circumferential direction.

The connecting extension 200 has an extension downstream surface 202 . The extension downstream surface 202 is the downstream surface of the connecting extension 200 . The extension downstream surface 202 has the configuration 1 that extends radially inward toward the downstream side. With this configuration 1, when the connection end portion 152 of the water purification cartridge PC1 is inserted into the connection reception portion 138 of the water purification cartridge mounting portion 134 of the water discharge head 108, the portion of the connection reception portion 138 that hits the downstream surface 202 of the extension portion is The center line of the connection end portion 152 and the center line of the connection receiving portion 138 are displaced in a direction that coincides with each other. The connecting end portion 152 of the water discharge head 108 is inserted into the connection receiving portion 138 of the water purification cartridge mounting portion 134 of the water discharge head 108, and the operability is improved.

On the other hand, the downstream end face 212 has configuration 2, being a radially extending, ie perpendicular to the axial direction surface. The water discharge head 108 has a pressing portion that is pressed against the water purification cartridge PC1 when the connection end portion 152 of the water purification cartridge PC1 is inserted into the connection receiving portion 138, and the pressing portion performs a specific function. A water discharge head with a water purification function, a water purification cartridge, and a faucet device are conceivable. This specific function includes, for example, switching of the water discharge state (raw water/purified water) and control of switching of the water discharge mode. In this case, since the surface of the portion of the connection end that presses the pressing portion extends in the radial direction, that is, is a surface that is perpendicular to the axial direction, the pressing portion can be pressed accurately and/or favorably. Effect 2 is produced. Effect 2 is manifested by extending the downstream end surface 212 in the radial direction.

Although the configuration 1 and the configuration 2 are arranged in the same axial region of the connecting end 152, both the effect 1 and the effect 2 can be achieved. Furthermore, since both structures are arranged in the same axial region of the connection end portion 152, as a result, the water discharge head with water purification function, the water purification cartridge, and the faucet device are prevented from becoming large, and the purification function portion is arranged. An increase in coverage can also be achieved.

The third cylindrical portion 164 has a circumferential surface 220 and a stepped surface 222 . Circumferential surface 220 is a circumferential surface. The centerline of the circumferential surface 220 is the centerline z1 of the water purification cartridge PC1. The step surface 222 is a plane. The step surface 222 extends radially. The step surface 222 is annular. The step surface 222 is formed over the entire circumferential direction. The interior of the third cylindrical portion 164 is the purified water flow path WJ.

The holding cylindrical portion 166 has a circumferential surface 230 and a stepped surface 232 . Circumferential surface 230 is a circumferential surface. The centerline of the circumferential surface 230 is the centerline z1 of the water purification cartridge PC1. The step surface 232 is a plane. The step surface 232 extends radially. The step surface 232 is annular. The step surface 232 is formed over the entire circumferential direction. The step surface 232 connects the upstream side of the circumferential surface 220 and the downstream side of the circumferential surface 230 .

The connecting end 152 has a purified water outlet hole 240 . The first annular packing s1 is located downstream of the purified water outlet hole 240. As shown in FIG. The second annular packing s2 is located upstream of the purified water outlet hole 240. As shown in FIG. The purified water outlet hole 240 is positioned between the first cylindrical portion 160 (tip portion 170 ) and the second cylindrical portion 162 . The first cylindrical portion 160 is spaced apart from the second cylindrical portion 162, and this spacing defines a purified water outlet hole 240. As shown in FIG. Purified water outlet holes 240 are formed between the connecting extension portions 200 adjacent in the circumferential direction.

FIG. 10 is a partially enlarged view of FIG. 3(b). FIG. 10 is an enlarged view of the connection end 152 and its vicinity. As described above, the water purification cartridge mounting portion 134 of the water discharge head 108 has the connection receiving portion 138 . The connection receiving portion 138 has a first cylindrical receiving portion 254 and a second cylindrical receiving portion 256 . The first receiving cylindrical portion 254 is located downstream of the second receiving cylindrical portion 256 . The first receiving cylindrical portion 254 is located downstream of the second receiving cylindrical portion 256 . The inner diameter of the first receiving cylindrical portion 254 is smaller than the inner diameter of the second receiving cylindrical portion 256 . The outer diameter of the first receiving cylindrical portion 254 is smaller than the inner diameter of the second receiving cylindrical portion 256 .

The connection end 152 is watertightly connected to the connection receiver 138 . The first annular packing s1 and the second annular packing s2 ensure watertightness. The first cylindrical portion 160 (tip portion 170 ) of the connecting end portion 152 is inserted inside the first receiving cylindrical portion 254 . The first annular packing s1 is in close contact with the inner peripheral surface of the first receiving cylindrical portion 254. As shown in FIG. The second cylindrical portion 162 of the connecting end portion 152 is inserted inside the second receiving cylindrical portion 256 . The second annular packing s2 is in close contact with the inner peripheral surface of the second receiving cylindrical portion 256. As shown in FIG. An end surface 258 of the second receiving cylindrical portion 256 is in contact with the stepped surface 222 . This abutment positions the water purification cartridge PC1 in the axial direction.

The connection receiving portion 138 has a purified water passage WJ1 that separates the purified water discharged from the purified water outlet hole 240 from the raw water passage WG and constitutes a part of the purified water passage WJ (see FIGS. 5B and 10). ). The connection receiving portion 138 also has a raw water passage WG1 that separates the raw water from the purified water passage WJ1 and constitutes a part of the raw water passage WG (see FIGS. 4A and 10). The connection receiving portion 138 has a partition wall 260 forming the raw water passage WG1 (see FIG. 10). The partition wall 260 is connected to the downstream end of the first receiving cylindrical portion 254 . Partition wall 260 is positioned downstream of recess 176 . The partition wall 260 extends radially. Partition 260 forms raw water passage WG1 between partition 260 and recess 176 . The raw water passage WG1 forms a raw water passage WG penetrating in the left-right direction (see FIG. 4(a)). The raw water passage WG1 guides the raw water to the tip surface 174 of the water purification cartridge PC1. Raw water passage WG1 guides raw water to recess 176 . The tip surface 174 faces the raw water flow path WG. The recess 176 faces the raw water flow path WG. The first annular packing s1 and the second annular packing s2 prevent purified water coming out of the purified water outlet hole 240 from flowing into the raw water flow path WG. The first annular packing s1 prevents water from the raw water passage WG1 from flowing into the purified water passage WJ. The second annular packing s2 prevents water from the raw water flow path WG from flowing into the outlet of the purified water outlet hole 240. As shown in FIG. The second annular packing s2 prevents purified water coming out of the purified water outlet hole 240 from flowing into the raw water flow path WG.

A water permeable member 270 is installed downstream of the recess 176 (see FIG. 10). The water-permeable member 270 is arranged to face the tip surface 174 . The water-permeable member 270 is installed facing the raw water passage WG1. The water-permeable member 270 is arranged between the raw water passage WG1 and the tip surface 174 . The water-permeable member 270 is arranged between the raw water passage WG1 and the recess 176 . In this embodiment, the water permeable member 270 is a mesh. This net is a metal net (mesh metal net). The water-permeable member 270 does not block the flow of the raw water flow path WG. The water flow in the raw water passage WG1 can hit the tip surface 174 . The water flow in the raw water passage WG1 can flow into the recess 176 . The water-permeable member 270 can prevent foreign matter from entering the raw water passage WG1.

FIG. 11 is a partially enlarged view of FIG. 5(b). The purified water outlet hole 240 of the purified water cartridge PC1 has an outlet opening edge 242 . The outlet opening edge 242 has a radially inner edge 242a and a radially outer edge 242b. The radially inner edge 242a is generally circular. The center of the radial inner edge 242a is located on the center line z1 of the water purification cartridge PC1. The radially outer edge 242b is generally circular. The center of the radial outer edge 242b is positioned on the center line z1 of the water purification cartridge PC1. The radially inner edge 242a is located radially inward of the radially outer edge 242b. The radially inner edge 242a is located downstream of the radially outer edge 242b.

A dashed line in FIG. 11 is a straight line L1 connecting the radially inner edge 242a and the radially outer edge 242b. A straight line L2 perpendicular to the straight line L1 is indicated by a chain double-dashed line in FIG. The straight line L2 is inclined radially outward toward the downstream side. A double arrow θ in FIG. 11 indicates an angle between the center line z1 of the water purification cartridge PC1 and the straight line L2. This angle θ is also referred to as an aperture tilt angle.

A double-headed arrow S1 in FIG. The outlet opening edge 242 has a radial opening width S1. The radial opening width S1 is the radial distance between the radially inner edge 242a and the radially outer edge 242b. A double arrow V in FIG. 11 indicates the axial width of the outlet opening edge 242 . The outlet opening edge 242 has an axial width V. As shown in FIG. The axial width V is the axial distance between the radially inner edge 242a and the radially outer edge 242b.

The purified water outlet hole 240 penetrates in the axial direction. In other words, the purified water outlet holes 240 are connected in the axial direction. FIG. 12 is an enlarged cross-sectional view in which a part of FIG. 11 is enlarged. In a cross section along the center line z1, the purified water outlet hole 240 allows the straight line X extending in the axial direction to pass through (see arrow y1 in FIG. 12). In a cross-section along the center line z1, the purified water outlet hole 240 has, as the straight line X, a straight line X1 located on the outermost radial direction and a straight line X2 located on the innermost radial direction. The straight line X1 and the straight line X2 are separated in the radial direction. That is, there is a radial distance between straight line X1 and straight line X2. This radial distance is also referred to as a front-to-rear penetration width. The purified water outlet hole 240 has a front-to-rear through width S2. In this embodiment, the front-rear through width S2 is equal to the radial opening width S1.

The width of the first groove 172 is indicated by a double arrow M1 in FIG. The groove width M1 (mm) is measured along the axial direction. The width of the second groove 210 is indicated by a double arrow M2 in FIG. The groove width M2 (mm) is measured along the axial direction. The groove width M1 is larger than the groove width M2.

In the present application, the cross-sectional diameter of the first annular packing s1 is defined as the cross-sectional diameter D1 (mm), and the cross-sectional diameter of the second annular packing s2 is defined as the cross-sectional diameter D2 (mm). Note that the cross-sectional diameter D1 is the diameter of the first annular packing s1 alone. That is, the cross-sectional diameter D1 is measured in a state where no external force is applied to the first annular packing s1. Similarly, the cross-sectional diameter D2 is the diameter of the second annular packing s2 alone. That is, the cross-sectional diameter D2 is measured in a state where no external force is applied to the second annular packing s2.

Cross-sectional diameter D1 is smaller than cross-sectional diameter D2. The cross-sectional diameter D1 is smaller than the groove width M1. The cross-sectional diameter D2 is smaller than the groove width M2.

As shown in FIG. 9, the groove width M1 is larger than the cross-sectional diameter D1 of the first annular packing s1. In the first groove 172, the first annular packing s1 has an axial clearance. In the first groove 172, the first annular packing s1 can move axially.

A bottom surface 172a of the first groove 172 is a circumferential surface as a whole and has a diameter. The diameter of the bottom surface 172a varies depending on the axial position. In this embodiment, the diameter of the bottom surface 172a is smaller on the downstream side than on the upstream side. In FIG. 9, the first annular packing s1 is positioned furthest upstream in the first groove 172. In FIG. When the first annular packing s1 moves downstream within the first groove 172, the compression of the first annular packing s1 is released. Further, when the first annular packing s1 moves downstream in the first groove 172, the inner diameter of the first annular packing s1 becomes smaller and the outer diameter thereof also becomes smaller. The movement of the first annular packing s1 to the downstream side facilitates removal of the water purification cartridge PC1.

As shown in FIG. 9, the groove width M2 is larger than the cross-sectional diameter D2 of the second annular packing s2. In the second groove 210, the first annular packing s1 has an axial clearance. In the second groove 210, the second annular packing s2 can move axially.

The bottom surface 210a of the second groove 210 is a circumferential surface as a whole and has a diameter. The diameter of bottom surface 210a is greater than the diameter of bottom surface 172a. The diameter of the bottom surface 210a does not change with axial position. The bottom surface 210a has a constant diameter. In FIG. 9 , the second annular packing s2 is positioned furthest upstream in the second groove 210 . Even if the second annular packing s2 moves axially within the second groove 210, the degree of compression of the second annular packing s2 does not change.

A double arrow G1 in FIG. 9 indicates the outer diameter of the first annular packing s1. The outer diameter G1 is measured with the first annular packing s1 attached to the first groove 172 and the water purification cartridge PC1 not attached to the water discharge head . In other words, the outer diameter G1 is measured in the state of the water purification cartridge PC1 alone. A double arrow G2 in FIG. 9 indicates the outer diameter of the second annular packing s2. The outer diameter G2 is measured with the second annular packing s2 attached to the second groove 210 and the water purification cartridge PC1 not attached to the water discharge head . In other words, the outer diameter G2 is measured in the state of the water purification cartridge PC1 alone. In addition, when the diameter of the bottom surface of the groove changes as in the bottom surface 172a of the first groove 172, the outer diameters G1 and G2 of the annular packing are set so that the annular packing is located at the position where the outer diameter of the bottom surface of the groove is maximum. Measured as placed.

The outer diameter G1 of the first annular packing s1 is smaller than the outer diameter G2 of the second annular packing s2.

A double arrow W1 in FIG. 9 indicates the width obtained by subtracting the cross-sectional diameter D1 from the groove width M1. That is, W1=M1-D1. A double arrow W2 in FIG. 9 indicates the width obtained by subtracting the cross-sectional diameter D2 from the groove width M2. W2=M2-D2. It should be noted that the first annular packing s1 and the second annular packing s2 in FIG. 9 are in the installed state and therefore compressed. Therefore, the cross-sectional width of the first annular packing s1 in FIG. 9 is not exactly the cross-sectional diameter D1. Similarly, the cross-sectional width of the second annular packing s2 in FIG. 9 is not the cross-sectional diameter D2. From this point of view, it is inappropriate to show the width W1 and the width W2 in FIG. 9, but for the sake of clarity, the width W1 and the width W2 are shown in FIG. Similarly, although it is inappropriate to show cross-sectional diameter D1 and cross-sectional diameter D2 in FIG. 9, cross-sectional diameter D1 and cross-sectional diameter D2 are shown in FIG. 9 for clarity.

Width W1 is greater than width W2. In other words, the difference (M1-D1) is greater than the difference (M2-D2).

Calcium contained in water, contaminants, and the like accumulate at the seal portion sealed by the annular packing, causing the annular packing to stick. In addition, the annular packing that is constantly exposed to water swells, and this swelling can also promote the fixation. Due to this fixation, it becomes difficult to remove the water purification cartridge PC1 from the connection receiving portion 138 . In addition, when a large force is required for removal, a load is applied to the annular packing, which may promote deterioration of the annular packing.

Providing the width W1 and the width W2 facilitates deformation of the annular packings s1 and s2 when removing the water purification cartridge PC1. Therefore, the detachability is improved. Also, the annular packings s1 and s2 can move within the groove. Therefore, the adhered portion is peeled off step by step, and the detachability is improved.

This embodiment has the following effects.

[Effect of G1 < G2]
In the water purification cartridge PC1, the outer diameter G1 of the downstream first annular packing s1 is smaller than the outer diameter G2 of the upstream second annular packing s2 (see FIG. 9).

This configuration improves improvement target 1 described above. Since the outer diameter G1 of the first annular packing s1 on the downstream side is small, the probability of it being rubbed against the edge 259 of the second receiving cylindrical portion 256 is low (see FIG. 10). Therefore, unlike the prior art (FIG. 13), there is almost no rubbing twice in one insertion. Therefore, damage to the first annular packing s1 on the downstream side is suppressed (packing damage suppression effect).

Furthermore, this configuration improves improvement target 2 described above. Since the outer diameter G1 of the first annular packing s1 is small, the outer diameter of the first cylindrical portion 160 on which the first annular packing s1 is arranged is also small (see FIG. 7A). Therefore, in the initial stage of inserting the water purification cartridge PC1, even if the center line z1 of the water purification cartridge PC1 is inclined, the probability that the first cylindrical portion 160 hits the inner surface of the second receiving cylindrical portion 256 is low (see FIG. 10). Therefore, damage to the inner surface of the connection receiving portion 138 is suppressed (receiving portion damage suppression effect).

Furthermore, the configuration of G1<G2 makes it easier to incline the straight line L2 (FIG. 11), which is the direction of the purified water outlet hole 240, and to allow the purified water outlet hole 240 to pass through in the axial direction. Therefore, this configuration also contributes to the improvement of the improvement target 3 and the improvement target 4.

If the outer diameter G1 of the first annular packing s1 is too small, the strength of the tip portion 170 of the water purification cartridge PC1 tends to decrease, and the watertightness of the first annular packing s1 tends to decrease. From this point of view, the outer diameter G1 is preferably 7 mm or more, more preferably 9 mm or more, and even more preferably 10 mm or more. If the outer diameter G1 is too large, the water purification cartridge PC1 and the water discharge head 108 will be large, and the water faucet will tend to be large. From this point of view, the outer diameter G1 is preferably 18 mm or less, more preferably 15 mm or less, and even more preferably 13 mm or less. In the above embodiment, the outer diameter G1 is 11 mm.

If the outer diameter G2 of the second annular packing s2 is too small, the flow rate of purified water tends to decrease. From this point of view, the outer diameter G2 is preferably 12 mm or more, more preferably 14 mm or more, and even more preferably 16 mm or more. If the outer diameter G2 is too large, the water purification cartridge PC1 and the water discharge head 108 will be large, and the water faucet will tend to be large. From this point of view, the outer diameter G2 is preferably 25 mm or less, more preferably 23 mm or less, and even more preferably 21 mm or less. In the above embodiment, the outer diameter G2 is 18.8 mm.

If the difference (G2-G1) is too small, the above-described packing damage prevention effect and receiving portion damage prevention effect will be reduced, and the improvement effects of improvement object 3 and improvement object 4 may also be reduced. Also, if the difference (G2-G1) is too small, the flow rate of purified water tends to decrease. From these points of view, the difference (G2-G1) is preferably 3 mm or more, more preferably 4 mm or more, and even more preferably 6 mm or more. If the difference (G2-G1) is too large, the water purification cartridge PC1 and the water discharge head 108 will be large, and the faucet will tend to be large. From this point of view, the difference (G2-G1) is preferably 15 mm or less, more preferably 12 mm or less, and even more preferably 10 mm or less. In the above embodiment, the difference (G2-G1) is 7.8mm.

If the ratio (G2/G1) is too small, the effects of suppressing damage to the packing and the effect of suppressing damage to the receiving part described above may be reduced, and the improvement effects of the improvement targets 3 and 4 may also be reduced. Moreover, the flow volume of clean water tends to decrease that G2/G1 is too small. From this viewpoint, G2/G1 is preferably 1.2 or more, more preferably 1.3 or more, and still more preferably 1.5 or more. If G2/G1 is excessively large, the water purification cartridge PC1 and the water discharge head 108 become large, and the faucet tends to become large. From this viewpoint, G2/G1 is preferably 2.5 or less, more preferably 2.3 or less, and even more preferably 1.9 or less. In the above embodiment, G2/G1 is 1.7.

[Effect of opening inclination angle θ]
As shown in FIG. 11, the purified water outlet hole 240 (outlet opening edge 242) has an opening inclination angle θ.

This opening inclination angle θ improves improvement target 3 described above. Due to the opening inclination angle θ, purified water can flow obliquely forward through the purified water outlet hole 240 while the axial length of the purified water outlet hole 240 is suppressed. Since the axial length of the purified water outlet hole 240 is suppressed, it is suppressed that the overall length of the water purification cartridge PC1 is increased and the water purification performance (length of the water purification material) is sacrificed (axial length suppression effect). In addition, since the purified water is discharged obliquely forward from the purified water outlet hole 240, the purified water is prevented from hitting the surface of the flow path forming member perpendicularly, and the flow path resistance can be reduced (flow path resistance reduction effect).

Furthermore, this opening inclination angle θ improves the improvement target 4 described above. In the configuration shown in FIG. 13, water is less likely to flow into the gap 19 between the radial tip 17 of the wall located upstream of the downstream O-ring 13a and the opposing member. This is because the direction in which the gap 19 extends is the axial direction, whereas the direction of the water flow adjacent to the gap 19 is substantially the radial direction (see the arrow in FIG. 13). Therefore, water tends to stay in the gap 19, and water scale and dirt tend to accumulate in the gap 19. - 特許庁On the other hand, in the embodiment of FIG. 11, the opening inclination angle θ is less than 90°, and due to this angle θ, the purified water outlet hole 240 can generate water flow obliquely forward (see arrow y2 in FIG. 12). ). This obliquely forward water flow includes an axially forward component, and tends to flow into the gap 280 between the rear wall portion 173 b and the first receiving cylindrical portion 254 . Therefore, water is less likely to remain in the gap 280, and water scale and dirt are less likely to accumulate in the gap 280. - 特許庁As described above, if there is a deposit in the gap 280, the deposit is scraped out by the first annular packing s1 when the water purification cartridge PC1 is taken out, and easily enters the water purification channel WJ from the water purification outlet hole 240. However, in the gap 280 where water is less likely to stay, the deposit is suppressed, and the problem of the scraped-out deposit flowing into the purified water flow path WJ is suppressed (deposit suppression effect).

If the opening inclination angle θ is too small, the connection end portion 152 becomes long and the effect of suppressing the length in the axial direction is reduced. From this point of view, the opening inclination angle θ is preferably 30° or more, more preferably 40° or more, and even more preferably 50° or more. If the opening inclination angle θ is excessively large, the effect of reducing flow path resistance and the effect of suppressing deposits are reduced. From this viewpoint, the opening inclination angle θ is preferably 80° or less, more preferably 70° or less, and even more preferably 60° or less. In this embodiment, the opening inclination angle θ is 56°.

[Effect of purified water outlet hole through axial direction]
As described above, the purified water outlet hole 240 penetrates in the axial direction (see arrow y1 in FIG. 12). As a result, the water flow easily enters the gap 280, further enhancing the above-described effect of suppressing deposits. In addition, since the water passing through the purified water outlet hole 240 easily flows in the axial direction, the flow path resistance reduction effect described above is further enhanced.

If the front-to-rear penetration width S2 (see FIG. 12) is too small, the effect of suppressing deposits and the effect of reducing flow path resistance are reduced. From this point of view, the front-rear penetration width S2 is preferably 1.05 mm or more, more preferably 1.1 mm or more. If the front-rear penetration width S2 is excessively large, the outer diameter G2 of the second annular packing s2 becomes large, and the water purification cartridge PC1 and the water discharge head 108 become large. Further, when the outer diameter G2 increases, the watertightness caused by the second annular packing s2 tends to deteriorate. From these points of view, the front-rear penetration width S2 is preferably 5 mm or less, more preferably 3 mm or less, and even more preferably 2 mm or less. In this embodiment, the front-to-rear penetration width S2 is 1.1 mm.

If the radial opening width S1 (see FIG. 11) is too small, the effect of suppressing deposits and the effect of reducing flow path resistance are reduced. From this point of view, the radial opening width S1 is preferably 1.05 mm or more, more preferably 1.1 mm or more. If the radial opening width S1 is excessively large, the outer diameter G2 of the second annular packing s2 becomes large, and the water purification cartridge PC1 and the water discharge head 108 become large. Further, when the outer diameter G2 increases, the watertightness caused by the second annular packing s2 tends to deteriorate. From these points of view, the radial opening width S1 is preferably 5 mm or less, more preferably 3 mm or less, and even more preferably 2 mm or less. In this embodiment, the radial opening width S1 is 1.1 mm.

[Effect of D1 < D2]
As described above, the cross-sectional diameter D1 of the first annular packing s1 is smaller than the cross-sectional diameter D2 of the second annular packing s2.

If the outer diameter of the annular packing is small, the ease of handling of the annular packing deteriorates, for example, it becomes difficult to extend the annular packing. Therefore, it is difficult to fit an annular packing having a small outer diameter into the groove. That is, an annular packing with a small outer diameter is less mountable, and an annular packing with a larger outer diameter is more easily mountable.

If the cross-sectional diameter of the annular packing is small, the annular packing can be easily stretched and can be easily installed in the groove. That is, the mountability of the annular packing with a small cross-sectional diameter is high. Annular packing with a large cross-sectional diameter is difficult to stretch and has low wearability.

Annular packings with a small cross-sectional diameter have a small possible crushing allowance and a poor seal. An annular packing with a large cross-sectional diameter can have a large crushing margin, and therefore has a high sealing performance. Also, if the crushing margin is large, it is easy to ensure the sealing performance even if there is a manufacturing dimensional error in the peripheral members.

In the above embodiment, the first annular packing s1 on the downstream side may have a reduced mountability due to the small outer diameter G1. Therefore, by reducing the cross-sectional diameter D1, the wearability is improved.

On the other hand, the second annular packing s2 on the upstream side has a high mountability due to the large outer diameter G2, and has a margin in mountability. For this reason, the cross-sectional diameter D2 is increased to enhance the sealing performance.

From the viewpoint of sealing performance, the cross-sectional diameter D1 of the first annular packing s1 is preferably 1.0 mm or more, more preferably 1.2 mm or more, and even more preferably 1.3 mm or more. From the viewpoint of wearability, the cross-sectional diameter D1 is preferably 2.0 mm or less, more preferably 1.9 mm or less, and even more preferably 1.7 mm or less. In the above embodiment, the cross-sectional diameter D1 is 1.5 mm.

From the viewpoint of sealing performance, the cross-sectional diameter D2 of the second annular packing s2 is preferably 1.3 mm or more, more preferably 1.5 mm or more, and even more preferably 1.7 mm or more. From the viewpoint of wearability, the cross-sectional diameter D2 is preferably 3.0 mm or less, more preferably 2.5 mm or less, and even more preferably 2.3 mm or less. In the above embodiment, the cross-sectional diameter D2 is 1.9 mm.

If the cross-sectional diameter D2 is too small, the sealing performance of the second annular packing s2 tends to deteriorate. In other words, if the cross-sectional diameter D2 is too small or the cross-sectional diameter D1 is too large, the overall performance of watertightness and wearability is lowered. From this point of view, the difference (D2-D1) is preferably 0.1 mm or more, more preferably 0.2 mm or more, and even more preferably 0.3 mm or more. If the cross-sectional diameter D2 is too large, the attachment of the second annular packing s2 is likely to be poor, and if the cross-sectional diameter D1 is too small, the sealing performance of the first annular packing s1 is likely to be poor. In other words, if the cross-sectional diameter D2 is too large or the cross-sectional diameter D1 is too small, the overall performance of watertightness and mountability is lowered. From this point of view, the difference (D2-D1) is preferably 1.0 mm or less, more preferably 0.8 mm or less, and even more preferably 0.6 mm or less. In the above embodiment, the difference (D2-D1) is 0.4mm.

If the cross-sectional diameter D2 is too small or the cross-sectional diameter D1 is too large, the overall performance of watertightness and wearability will be degraded. From this viewpoint, the ratio (D2/D1) is preferably 1.05 or more, more preferably 1.1 or more, and even more preferably 1.2 or more. If the cross-sectional diameter D2 is too large or the cross-sectional diameter D1 is too small, the overall performance of watertightness and wearability will be degraded. From this viewpoint, the ratio (D2/D1) is preferably 2.0 or less, more preferably 1.5 or less, and even more preferably 1.3 or less. In the above embodiment, the ratio (D2/D1) is 1.27.

[Effect of W1>W2]
As described above, width W1 is greater than width W2. In other words, the difference (M1-D1) is greater than the difference (M2-D2) (see FIG. 9).

Since the second annular packing s2 on the upstream side has a large cross-sectional diameter D2, it is easily deformed when the water purification cartridge PC1 is removed. Therefore, the second annular packing s2 is unlikely to become a factor that deteriorates the detachability. On the other hand, since the first annular packing s1 on the downstream side has a small cross-sectional diameter D1, it is difficult to deform when removing the water purification cartridge PC1. Therefore, the first annular packing s1 tends to be a factor that deteriorates the detachability. Therefore, by making the width W1 of the first annular packing s1, which is difficult to deform, larger than the width W2, the detachability is improved. If both the width W1 and the width W2 are increased, the axial length of the connecting end portion 152 is increased, resulting in an increase in the length of the water purification cartridge PC1 or a decrease in water purification performance (length of the water purification material). These inconveniences are suppressed by making the width W2 smaller than the width W1.

From the standpoint of removability, the width W1 is preferably 0.7 mm or more, more preferably 0.9 mm or more, and even more preferably 1.1 mm or more. From the viewpoint of suppressing lengthening of the water purification cartridge PC1 and deterioration of water purification performance, the width W1 is preferably 2.0 mm or less, more preferably 1.8 mm or less, and even more preferably 1.5 mm or less. In this embodiment, the width W1 is 1.3 mm.

From the standpoint of removability, the width W2 is preferably 0.2 mm or more, more preferably 0.3 mm or more, and even more preferably 0.4 mm or more. From the viewpoint of suppressing lengthening of the water purification cartridge PC1 and deterioration of water purification performance, the width W2 is preferably 1.5 mm or less, more preferably 1.1 mm or less, and still more preferably 0.8 mm or less. In this embodiment, the width W2 is 0.6 mm.

From the viewpoint of suppressing excessively small width W1 and excessively large width W2, the difference (W1-W2) is preferably 0.1 mm or more, more preferably 0.3 mm or more, and even more preferably 0.5 mm or more. From the viewpoint of suppressing excessive width W1 and excessively small width W2, the difference (W1-W2) is preferably 1.5 mm or less, more preferably 1.2 mm or less, and even more preferably 0.8 mm or less. In this embodiment, the difference (W1-W2) is 0.7 mm.

From the viewpoint of suppressing excessively small width W2 and excessively large width W1, the ratio (W2/W1) is preferably 0.2 or more, more preferably 0.3 or more, and even more preferably 0.4 or more. From the viewpoint of suppressing the excessive width W2 and the excessively small width W1, the ratio (W2/W1) is preferably 0.9 or less, more preferably 0.8 or less, and even more preferably 0.6 or less. In this embodiment, the ratio (W2/W1) is 0.46.

[Effect of concave part]
As described above, the outer surface of the tip portion 170 of the water purification cartridge PC1 has a concave portion 176 (see FIG. 9).

Since the first annular packing s1 is arranged at the tip portion 170, the tip portion 170 requires a predetermined axial length. A first groove 172 is arranged in the tip portion 170, and the dimensional accuracy of the bottom surface 172a is an important factor for enhancing the sealing performance of the first annular packing s1.

If the inside of the packing arrangement portion having a predetermined axial length is solid, sink marks (molding shrinkage) during molding become large. This phenomenon can occur in both thermoplastic resins and thermosetting resins. For example, in injection molding of thermoplastic resins, sink marks can occur during cooling. For example, in molding a thermosetting resin, sink marks may occur when the resin is cured. In addition, if the inside of the packing arrangement portion having a predetermined axial length is solid, there will be a large variation in dimensions among individuals.

By providing the cavity radially inward of the packing arrangement portion, the sink marks are suppressed and the dimensional variation is also suppressed. Therefore, the dimensional accuracy of the bottom surface 172a of the first groove 172 is improved, and the sealing performance by the first annular packing s1 is improved.

The concave portion positioned radially inward of the packing arrangement portion can be provided on the outer surface of the tip portion 170 like the water purification cartridge PC1, but can also be provided on the inner surface of the tip portion 170. FIG.

When the concave portion is provided on the inner surface of the tip portion 170, this concave portion faces the purified water flow path WJ. Purified water can flow into and stay in this recess. From a sanitary point of view, it is not preferable for purified water from which chlorine has been removed to stay in the recess. In contrast, in this embodiment, the recess 176 is provided on the outer surface of the distal end portion 170 . The recess 176 faces the raw water flow path WG. It is the raw water that stays in the recess 176 . In this embodiment, the situation that the purified water from which chlorine has been removed stays in the concave portion is avoided.

In addition, when the concave portion is provided on the inner surface of the tip portion 170, the concave portion complicates the shape of the flow path radially inside the purified water outlet hole 240, and turbulence is likely to occur. This turbulence can reduce the flow rate at the purified water outlet hole 240 . Since purified water passes through the water purification function part of the water purification cartridge PC1, the water pressure in the purified water channel WJ is lower than the water pressure in the raw water channel WG. When the flow rate at the purified water outlet hole 240 decreases due to the turbulent flow, the flow rate in the purified water flow path WJ further decreases. Such a situation is avoided in this embodiment.

A double arrow T in FIG. 9 indicates the shortest distance between the bottom surface 172a of the first groove 172 and the recess 176 (side surface 178). If the shortest distance T is too short, the strength may be lowered and the sealing performance may be lowered due to the deformation of the bottom surface 172a. From this point of view, the shortest distance T is preferably 0.5 mm or longer, more preferably 1.0 mm or longer, and even more preferably 1.2 mm or longer. If the shortest distance T is too large, the aforementioned sink marks will increase. From this point of view, the shortest distance T is preferably 3.0 mm or less, more preferably 2.0 mm or less, and even more preferably 1.8 mm or less. In the above embodiment, the shortest distance T is 1.5 mm.

In switching between the raw water dispensing state and the purified water dispensing state, the first valve 130 (raw water isolation valve) or the second valve 132 (purified water isolation valve) is momentarily closed. In switching from the raw water discharge state to the purified water discharge state, the raw water flow path WG with high water pressure is instantaneously shut off, so water hammer or high water pressure is applied from the first valve 130 (raw water cutoff valve) to the raw water flow path WG. is transmitted to the upstream side of

As described above, the outer surface of the tip portion 170 faces the raw water flow path WG. (See FIG. 11). This water hammer or high water pressure acts on the distal end portion 170, thereby causing the water purification cartridge PC1 to swing. This oscillation can occur every time the water discharge is switched. Due to this swinging, sticking of the packings s1 and s2 can be suppressed.

As described above, the tip portion 170 is provided with the partition wall 190 . Partition wall 190 is impermeable to water. Moreover, the partition wall 190 is provided at a position that intersects the center line z1 of the water purification cartridge PC1. Therefore, the water hammer or high water pressure acting on the partition wall 190 can effectively swing the water purification cartridge PC1. Therefore, sticking of the packings s1 and s2 can be effectively suppressed.

The partition wall 190 preferably extends radially, but does not have to extend radially. In the above embodiment, the partition wall 190 extends radially. Therefore, the water hammer or high water pressure acting on the partition wall 190 can be effectively converted into an axial force. This axial force can effectively swing the water purification cartridge PC1 in the axial direction (front-rear direction).

The centerline of the partition wall 190 should match the centerline z1 of the water purification cartridge PC1, but it does not have to match the centerline z1 of the water purification cartridge PC1. In the above embodiment, the centerline of the partition wall 190 matches the centerline z1 of the water purification cartridge PC1. Therefore, the pressure acting on the partition wall 190 can be effectively transmitted to the water purification cartridge PC1.

As described above, the outer surface of tip 170 is provided with recess 176 . The recesses 176 can effectively trap water hammers or high water pressures as compared to a flat surface or the like without recesses. The recessed portion 176 can facilitate rocking of the water purification cartridge PC1. Therefore, sticking of the packings s1 and s2 can be effectively suppressed.

The raw water passage WG1 extends radially. By providing the concave portion 176, the water flow of the raw water passage WG1 extending along the radial direction can be effectively captured. The recess 176 can effectively trap water hammer or high water pressure in the radially extending raw water passage WG1.

As shown in FIG. 8, the recess 176 has sides 178 and a bottom 180 . The bottom surface 180 extends radially. Thus, a water hammer or high water pressure acting on the bottom surface 180 can cause axial rocking. Side 178 extends axially. Thus, a water hammer or high water pressure acting on side 178 can cause radial rocking. Swinging in two directions can effectively suppress sticking of the packings s1 and s2.

In the above embodiment, O-rings are used as the annular packings s1 and s2. The cross-sectional shape of this O-ring is circular. The cross-sectional shape of the annular packing may not be circular. For example, an O-ring having an elliptical cross section may be used as the annular packing. Annular packing is not limited to O-rings. Moreover, the cross-sectional shape of the annular packing is not limited. For example, a rectangular packing with a square cross section, a U packing with a U-shaped cross section, a V packing with a V-shaped cross section, a Y packing with a Y-shaped cross section, and an X packing with an X-shaped cross section can be used as the annular packing. An O-ring is preferable, and an O-ring having a circular cross section is particularly preferable from the viewpoint of suppressing adhesion between the water purification cartridge and peripheral members and the annular packing and ensuring sealing performance (watertightness).

Examples of the material of the connection end portion 152 include resin and metal. From the viewpoint of cost, when the material is metal, the manufacturing method of the connecting end portion 152 is preferably sintering, casting or forging. From the viewpoint of cost, resin is preferable to metal. The resin includes thermoplastic resins and thermosetting resins. Thermoplastic resins that are easy to mold are preferred. From the viewpoint of moldability, polyoxymethylene (POM), polyphenylene sulfide (PPS), acrylonitrile-butadiene-styrene copolymer (ABS) and polypropylene (PP) are more preferable. From the standpoint of moldability and cost, acrylonitrile-butadiene-styrene copolymer (ABS) and polypropylene (PP) are particularly preferred.

Examples of the material of the tip portion 170 include resin and metal. From the viewpoint of cost, when the material is metal, the manufacturing method of the tip portion 170 is preferably sintering, casting or forging. From the viewpoint of cost, resin is preferable to metal. The resin includes thermoplastic resins and thermosetting resins. Thermoplastic resins that are easy to mold are preferred. From the viewpoint of moldability, polyoxymethylene (POM), polyphenylene sulfide (PPS), acrylonitrile-butadiene-styrene copolymer (ABS) and polypropylene (PP) are more preferred. From the standpoint of moldability and cost, acrylonitrile-butadiene-styrene copolymer (ABS) and polypropylene (PP) are particularly preferred.

In the water purification cartridge PC1 of the above embodiment, the intermediate portion 150 has the permeable portion 151 that allows water to permeate from the outer peripheral surface of the water purification cartridge PC1 to the inside. The configuration of the intermediate portion 150 is not limited to this aspect. For example, the outer peripheral surface of the water purification cartridge PC1 may be formed of a non-permeable outer peripheral wall, and the permeable portion may be provided inside the outer peripheral wall. In this case, the inflow of water from the rear end of the water purification cartridge PC1 may be allowed. For example, an inlet may be provided at the upstream end (rear end) of the water purification cartridge PC1. This inlet may be provided in the posterior forming portion 154 . Water can flow into the water purification cartridge PC<b>1 from this inlet, pass through the permeable portion, and reach the connecting end portion 152 .

In the above embodiment, the water purification function part is the permeation part, and purified water is generated by allowing the raw water to permeate the permeation part. As mentioned above, this permeation part is only one example of the water purification function part. Purified water may be produced without passing through the permeable portion. For example, purified water can also be produced by the water purification cartridge having a metal material, and metal ions having an effect of sterilization, antibacterial, sterilizing, or inhibiting growth of bacteria are released from the metal material.

Purified water in the present application is a concept including the generated water of (1) and (2) below.
(1) Generated water from which substances or ions in water have been removed by an adsorbent or filtration membrane.
(2) Generated water obtained by adding metal ions, electrons, substances, etc. to water to impart beneficial functions to water, such as adding metal ions to water in order to give the water a function such as sterilization.

Specifically, purified water in the present application is a concept including water generated by function A and/or function B below. In other words, the water purification function part in this application is a concept including a function part having the following function A and/or function B.

[Function A]
Function A is one or more functions selected from the group consisting of A1, A2, A3, A4 and A5 below.
A1: A function that uses an adsorbent such as activated carbon to adsorb and remove substances in water.
A2: A function of filtering substances in water using a filter medium. Preferably, the filter medium is a filtration membrane such as a reverse osmosis membrane, an ultrafiltration membrane, a microfiltration membrane, a nanofiltration membrane, or a porous hollow fiber membrane, and the function of filtering substances in water using this filtration membrane.
A3: A function to take in and remove metal ions, etc. in water using an ion-exchange resin or the like.
A4: A function of releasing metal ions having effects of sterilizing, antibacterial, sterilizing and/or inhibiting growth of bacteria from metal materials.
A5: A function of releasing metal ions from a metal material and generating active oxygen by taking in oxygen in water electrons generated with the release of the metal ions.

Substances in water to be purified include chlorine, volatile organic compounds, pesticide substances, musty substances, and heavy metals. Preferably one or more selected from the group consisting of chlorine, volatile organic compounds, pesticides, musty substances and heavy metals are removed.

In addition, in this application, "chlorine" is a concept including residual chlorine in tap water. This residual chlorine includes free residual chlorine and combined residual chlorine. Free residual chlorine includes hypochlorous acid and hypochlorite ions. Combined residual chlorine includes monochloramine, dichloramine and trichloramine. These residual chlorines can be produced when chlorine gas is dissolved in water for the purpose of disinfecting the water.

Examples of the volatile organic compounds include chloroform, bromodichloromethane, dibromochloromethane, broroform, tetrachloroethylene, trichloroethylene, 1,1,1-trichloroethane, total trihalomethanes, and the like. Preferably one or more selected from the group consisting of chloroform, bromodichloromethane, dibromochloromethane, broroform, tetrachloroethylene, trichloroethylene, 1,1,1-trichloroethane, total trihalomethanes is removed.

Examples of the agricultural chemical substance include 2-chloro-4,6-bistilamino-1,3,5-triazine. Preferably 2-chloro-4,6-bis-tylamino-1,3,5-triazine is removed.

Examples of the musty substance include 2-methylisoborneol, geosmin, and phenols. Preferably one or more selected from the group consisting of 2-methylisoborneol, geosmin and phenols is removed.

Examples of the heavy metals include lead, mercury, copper, arsenic and cadmium. Preferably one or more selected from the group consisting of lead, mercury, copper, arsenic and cadmium is removed.

Zinc ions and silver ions are exemplified as metal ions for the function A4. Preferably, one or more selected from the group consisting of zinc ions and silver ions are released.

Bacteria in function A4 include Escherichia coli and staphylococci, and include various bacteria defined (included) as general bacteria. Preferably, one or more of these bacteria are sterilized, antibacterial, sterilized, or inhibited from growing.

Active oxygen in function A5 can decompose organic matter such as bacteria. Examples of this bacterium include Escherichia coli and Staphylococcus, and also includes miscellaneous fungi defined (included) as general bacteria. Preferably, one or more of those bacteria are degraded.

A water purification cartridge having the function A1 is preferable from the viewpoint of being able to effectively remove chlorine and harmful substances and to reduce the manufacturing cost of the water purification cartridge. It should be noted that the water purification cartridge may have one or more functions selected from functions A2, A3, A4 and A5 and the function A1.

[Function B]
Function B is listed in "6 Water purifier" in Appended Table 2 (related to Article 2) of Miscellaneous Industrial Goods Quality Labeling Regulations (Revision date: March 30, 2017 / Enforcement date: April 1, 2017) It is a function to purify water using a defined filter media and/or media. In other words, the water purification cartridge conforms to the "6 Purified water It is preferable to have a water purification function part that purifies water using the filter medium and/or medium specified in the "equipment".

The water purification function part having the function A and/or function B may constitute a part of the water purification channel, may be arranged in the water purification channel, or may be distributed in the water purification channel. It may be arranged in a puddle.

The water purification cartridge may be an integral type in which the whole is inseparably integrated, or may be a composite type composed of a plurality of mutually separable members.

The composite type can have, for example, an adapter member and a cartridge main body. The adapter member may or may not be connectable to the cartridge main body. In other words, the adapter member may or may not be attachable to the cartridge main body. When the adapter member is attachable to the cartridge body, the adapter member may be detachably attached to the cartridge body, or may be irremovably attached to the cartridge body. The function of the adapter member is not limited. For example, the adapter member may have a function related to the operability of the operation section (push button) 114 .

The configurations of the adapter member and the cartridge body are not limited, and may be, for example, any of the following configurations B1 to B4.
B1: A configuration in which the adapter member is attached to the cartridge attachment portion while the adapter member is attached to the cartridge main body.
B2: A configuration in which the adapter member is attached to the cartridge attachment portion first, and then the cartridge main body is attached to the adapter member.
B3: A configuration in which the adapter member is attached to a part of the cartridge attachment portion and the cartridge main body is attached to the other portion of the cartridge attachment portion.
B4: A configuration in which the adapter member is first mounted on a part of the cartridge mounting portion, and then the cartridge main body is mounted on the adapter member and the other portion of the cartridge mounting portion.

In the configurations B1 to B4 described above, the adapter member may be configured to be detachably attached to the cartridge mounting portion, or may be configured to be irremovably attached. Preferably, the adapter member is detachably attached to the cartridge mounting portion.

The following remarks are disclosed with respect to the above-described embodiments.
[Appendix 1]
A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head with a water purification function,
It has a connection end connected to the connection receiving portion of the water purification cartridge mounting portion,
The connecting end portion has a purified water outlet hole, a first annular packing positioned downstream from the purified water outlet hole, and a second annular packing positioned upstream from the purified water outlet hole,
The water purification cartridge, wherein the outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing.
[Appendix 2]
the purified water outlet hole having an outlet opening rim;
the outlet opening edge has a radially inner edge and a radially outer edge;
In a cross section along the center line of the water purification cartridge, when a straight line passing through the radially inner edge and the radially outer edge is L1, and a straight line perpendicular to the straight line L1 is L2, the straight line L2 is , the water purification cartridge according to appendix 1, which is inclined so as to go radially outward as it goes downstream.
[Appendix 3]
3. The water purification cartridge according to appendix 1 or 2, wherein the water purification outlet hole penetrates in the axial direction.
[Appendix 4]
4. The water purification cartridge according to any one of appendices 1 to 3, wherein the cross-sectional diameter D1 of the first annular packing is smaller than the cross-sectional diameter D2 of the second annular packing.
[Appendix 5]
The connecting end portion has a first groove in which the first annular packing is arranged and a second groove in which the second annular packing is arranged,
The width M1 of the first groove is larger than the cross-sectional diameter D1,
The width M2 of the second groove is larger than the cross-sectional diameter D2,
The water purification cartridge according to appendix 4, wherein the difference (M1-D1) is greater than the difference (M2-D2).
[Appendix 6]
It has a purification material that can remove chlorine,
The connection end has a water-impermeable tip on which the first annular packing is arranged,
The material of the tip is resin,
The inner surface of the tip portion faces the purified water flow path,
The outer surface of the tip portion faces the raw water flow path,
The outer surface of the tip portion has a recess,
6. The water purification cartridge according to any one of appendices 1 to 5, wherein the cavity formed by the concave portion exists radially inside the first annular packing.
[Appendix 7]
a discharge port;
a raw water flow path;
a purified water channel;
a switching mechanism for switching between the raw water channel and the purified water channel;
a water purification cartridge for generating the purified water in the water purification channel;
a water purification cartridge mounting portion in which the water purification cartridge is arranged;
and
The water purification cartridge mounting portion has a connection receiving portion connected to the water purification cartridge,
The water purification cartridge has a connection end connected to the connection receiving portion,
The connection end is
It has a purified water outlet hole, a first annular packing positioned downstream from the purified water outlet hole, and a second annular packing positioned upstream from the purified water outlet hole,
The water discharge head with a water purification function, wherein the outer diameter of the first annular packing is smaller than the outer diameter of the second annular packing.
[Appendix 8]
A water faucet device comprising the water discharge head with a water purification function according to appendix 7.

This application also describes other inventions that are not included in the claimed inventions (including independent claims). Each form, member, configuration, etc. described in the claims and embodiments of the present application are recognized as inventions based on their effects.

Each of the forms, members, configurations, etc. shown in each of the above embodiments, even if not all of the forms, members, or configurations of these embodiments, It can be applied to all described inventions.

DESCRIPTION OF SYMBOLS 102... Faucet apparatus 104... Main-body part 106... Lever handle 108... Water discharge head 110... Water conveyance part 114... Operation part 134... Water purification cartridge mounting part 138... Connection Receiving portion 152 Connection end portion 154 Rear formation portion 160 First cylindrical portion 162 Second cylindrical portion 164 Third cylindrical portion 172 First groove 174 Tip surface 176 Recessed portion 178 Side surface of recessed portion 180 Bottom surface of recessed portion 190 Partition wall 210 Second groove 240 Purified water outlet hole 242 Outlet opening edge 254 First receiving cylindrical portion 256 Second receiving cylindrical portion PC1 Purified water cartridge s1 First annular packing s2 Second annular packing WJ Purified water channel WJ1 Purified water passage WG・・・Raw water passage WG1・・・Raw water passage

Claims (12)

A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a function of generating generated water containing metal ions having an effect of sterilization, antibacterial, sterilization or inhibition of bacterial growth,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate portion comprises a metal material for releasing metal ions having an effect of sterilization, antibacterial, sterilization or bacterial growth inhibition,
The water purification cartridge, wherein the first annular packing has an outer diameter G1 of 7 mm or more and 18 mm or less. A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a function of removing substances or ions in water,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate part has an adsorbent or a filtration membrane that removes substances or ions in water,
The water purification cartridge, wherein the first annular packing has an outer diameter G1 of 7 mm or more and 18 mm or less. A water purification cartridge disposed in a water purification cartridge mounting portion of a water discharge head having a function of generating generated water containing metal ions in water,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate portion has a metal material that produces water containing metal ions,
The water purification cartridge, wherein the first annular packing has an outer diameter G1 of 7 mm or more and 18 mm or less. A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a function of generating generated water containing metal ions having an effect of sterilization, antibacterial, sterilization or inhibition of bacterial growth,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate portion comprises a metal material for releasing metal ions having an effect of sterilization, antibacterial, sterilization or bacterial growth inhibition,
The water purification cartridge, wherein the outer diameter G2 of the second annular packing is 12 mm or more and 25 mm or less. A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a function of removing substances or ions in water,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate part has an adsorbent or a filtration membrane that removes substances or ions in water,
The water purification cartridge, wherein the outer diameter G2 of the second annular packing is 12 mm or more and 25 mm or less. A water purification cartridge disposed in a water purification cartridge mounting portion of a water discharge head having a function of generating generated water containing metal ions in water,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate portion has a metal material that produces water containing metal ions,
The water purification cartridge, wherein the outer diameter G2 of the second annular packing is 12 mm or more and 25 mm or less. A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a purified water flow channel and a raw water flow channel,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate portion comprises a metal material for releasing metal ions having an effect of sterilization, antibacterial, sterilization or bacterial growth inhibition,
The metal material constitutes a part of the water purification channel, is arranged in the water purification channel, or is arranged in a water pool portion that flows through the water purification channel ,
The water purification cartridge , wherein the first annular packing has an outer diameter G1 of 7 mm or more and 18 mm or less . A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a purified water flow channel and a raw water flow channel,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate part has an adsorbent or a filtration membrane that removes substances or ions in water,
The adsorbent or filtration membrane constitutes a part of the water purification channel, is arranged in the water purification channel, or is arranged in a water pool that flows through the water purification channel ,
The water purification cartridge , wherein the first annular packing has an outer diameter G1 of 7 mm or more and 18 mm or less . A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a purified water flow channel and a raw water flow channel,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate portion has a metal material that produces water containing metal ions,
The metal material constitutes a part of the water purification channel, is arranged in the water purification channel, or is arranged in a water pool portion that flows through the water purification channel ,
The water purification cartridge , wherein the first annular packing has an outer diameter G1 of 7 mm or more and 18 mm or less . A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a purified water flow channel and a raw water flow channel,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate portion comprises a metal material for releasing metal ions having an effect of sterilization, antibacterial, sterilization or bacterial growth inhibition,
The metal material constitutes a part of the water purification channel, is arranged in the water purification channel, or is arranged in a water pool portion that flows through the water purification channel ,
The water purification cartridge , wherein the outer diameter G2 of the second annular packing is 12 mm or more and 25 mm or less . A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a purified water flow channel and a raw water flow channel,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate part has an adsorbent or a filtration membrane that removes substances or ions in water,
The adsorbent or filtration membrane constitutes a part of the water purification channel, is arranged in the water purification channel, or is arranged in a water pool that flows through the water purification channel ,
The water purification cartridge , wherein the outer diameter G2 of the second annular packing is 12 mm or more and 25 mm or less . A water purification cartridge arranged in a water purification cartridge mounting portion of a water discharge head having a purified water flow channel and a raw water flow channel,
an intermediate portion, a rear forming portion arranged at the rear end portion of the intermediate portion, and a connection end arranged at the front end portion, having a purified water flow path therein, and connected to a connection receiving portion of the water purification cartridge mounting portion. and
The connection end is
a first annular packing;
a second annular packing positioned rearward of the first annular packing;
a first groove provided on the outer peripheral surface of the connection end portion and in which the first annular packing is arranged;
a second groove provided on the outer peripheral surface of the connection end portion and in which the second annular packing is arranged;
In a state in which the water purification cartridge is attached to the water purification cartridge mounting portion, the water purification channel is provided between the first annular packing and the second annular packing so as to communicate with the water purification channel formed isolated from the raw water channel. a purified water outlet hole;
and
The outer diameter G1 of the first annular packing is smaller than the outer diameter G2 of the second annular packing,
The intermediate portion has a metal material that produces water containing metal ions,
The metal material constitutes a part of the water purification channel, is arranged in the water purification channel, or is arranged in a water pool portion that flows through the water purification channel ,
The water purification cartridge , wherein the outer diameter G2 of the second annular packing is 12 mm or more and 25 mm or less .

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