JP2023095937A - Water discharge device - Google Patents

Abstract

To improve assemblability.SOLUTION: A water discharge device according to an embodiment has an internal flow channel unit, an outer shell member, an insertion member, and a sandwiching member. The internal flow channel unit is formed with an internal flow channel. The internal flow channel unit is inserted into the outer shell member. The insertion member is inserted into the internal flow channel unit from a direction crossing the insertion direction of the internal flow channel unit. The sandwiching member is inserted into the outer shell member from the insertion direction with respect to the outer shell member. The insertion member has a stopper formed to protrude from the outer peripheral surface. The stopper and the sandwiching member are located inside the outer shell member and outside the internal flow channel unit when the water discharge device is assembled. The stopper is positioned between the internal flow channel unit and the sandwiching member in a direction crossing the insertion direction of the insertion member.SELECTED DRAWING: Figure 5

Description

Disclosed embodiments relate to water discharging devices.

Conventionally, there has been known a water discharging device in which an internal flow channel member capable of mixing hot water and cold water is inserted into an outer shell member, and for example, mixed water in which hot water and cold water are mixed is discharged (see, for example, Patent Document 1). .

Japanese Patent Application Laid-Open No. 2002-228040

By the way, in a water discharging device in which an internal flow channel member is inserted into an outer shell member, since a part of the flow channel is formed between the outer shell member and the internal flow channel member, the outer shell member contains harmful metal such as lead. If it is made of an alloy, it may not be able to comply with the elution regulations, which are becoming stricter worldwide.

Accordingly, the present inventors devised a structure that suppresses the elution of metal components from the outer shell member by completing the flow path with an internal flow path member made of resin. In a water discharging device that does not allow water to flow between the outer shell member and the inner flow channel member, the inner flow channel member can be inserted into the outer shell member without providing a seal member or the like between the outer shell member and the inner flow channel member. can.

However, in such a water discharger, the position of the internal flow path member is not fixed with respect to the outer shell member. Therefore, there is room for improvement in terms of improving the ease of assembly.

An object of one aspect of the embodiment is to provide a water discharging device that improves assemblability.

A water discharging device according to an aspect of an embodiment includes an internal flow path unit in which an internal flow path is formed, an outer shell member into which the internal flow path unit is inserted, and an insertion direction of the internal flow path unit. an insertion member that is inserted into the internal channel unit from the direction thereof; and a clamping member that is inserted into the outer shell member from the insertion direction with respect to the outer shell member, the insertion member protruding from an outer peripheral surface of the outer shell member. the stopper and the clamping member are positioned inside the outer shell member and outside the internal flow path unit in the assembled state of the water discharging device; It is characterized by being positioned between the internal flow path unit and the holding member in a direction intersecting the insertion direction of the member.

By inserting the insertion member in a direction that intersects the insertion direction of the internal flow path unit, the position of the internal flow path unit with respect to the outer shell member can be fixed when assembling the water discharging device, improving the ease of assembly. be able to. In addition, since the stopper is positioned between the internal flow path unit and the clamping member in a direction that intersects the insertion direction of the insertion member, when force is applied in the direction in which the insertion member is pulled out, the stopper does not touch the clamping member. With a simple configuration, it is possible to prevent the insertion member from contacting and coming out in a direction intersecting the insertion direction of the internal channel unit.

Further, the insertion member is a connection member that allows water or hot water to flow into the internal flow path.

By using the insertion member as a connecting member for inflowing water or hot water, when assembling the water discharger, the position of the internal flow path unit with respect to the outer shell member can be adjusted without using other fixing members that are not part of the water discharger. can be fixed.

In addition, the internal flow path includes a hot water flow path through which the hot water flows and a water flow flow path through which the water flows, and the insertion member is a first hot water flow path that allows the hot water to flow into the hot water flow path. It is characterized by comprising a connection member and a second connection member that allows the water to flow into the water flow channel.

When assembling the water discharger, the position of the internal flow path unit can be fixed using the first connection member and the second connection member, and the position of the internal flow path unit can be further fixed with respect to the outer shell member. can.

According to one aspect of the embodiment, it is possible to improve assemblability.

FIG. 1 is a perspective view of a water discharger. FIG. 2 is a front view of the water discharger. FIG. 3 is a sectional view taken along line III--III in FIG. FIG. 4 is an exploded perspective view of part of the internal channel unit. 5 is an enlarged view of the vicinity of the first connection member in FIG. 3. FIG.

EMBODIMENT OF THE INVENTION Hereinafter, with reference to an accompanying drawing, embodiment of the discharging apparatus which this application discloses is described in detail. In addition, this invention is not limited by embodiment shown below.

The water discharge device 1 is a hot water mixing faucet capable of mixing hot water and cold water. A water discharging device 1 will be described with reference to FIGS. 1 to 3. FIG. FIG. 1 is a perspective view of the water discharging device 1. FIG. FIG. 2 is a front view of the water discharger 1. FIG. FIG. 3 is a sectional view taken along line III--III in FIG.

For convenience of explanation, FIGS. 1 to 3 show a three-dimensional orthogonal coordinate system including the Z-axis whose positive direction is vertically upward. The orthogonal coordinate system is also illustrated in other drawings.

The Cartesian coordinate system defines the positive direction of the X-axis as "left" and the negative direction of the X-axis as "right". In the orthogonal coordinate system, the positive direction of the Y-axis is defined as "forward" and the negative direction of the Y-axis is defined as "backward". In the orthogonal coordinate system, the positive direction of the Z-axis is defined as "upward" and the negative direction of the Z-axis is defined as "downward". Therefore, in the following description, the X-axis direction may be referred to as the horizontal direction, the Y-axis direction as the front-rear direction, and the Z-axis direction as the vertical direction.

The water discharger 1 includes a faucet body 2, a temperature control handle 3, a flow rate control handle 4, an internal channel unit 5, a water discharge pipe 6, and a hand shower (not shown). The water discharger 1 discharges mixed water in which water and hot water are mixed, or water from a water discharge pipe 6 or a hand shower.

The faucet main body 2 is cylindrical and extends in the left-right direction. The faucet body 2 is made of a metal member. The faucet main body 2 is formed with an inner peripheral wall 2a having a circular cross section perpendicular to the left-right direction. The axial direction of the faucet main body 2 coincides with the left-right direction. The outer shape of the faucet main body 2 is not limited to a cylindrical shape, and may be rectangular, for example. The faucet main body 2 constitutes an outer shell member.

An internal channel unit 5 is inserted into the faucet main body 2 in the left-right direction. That is, the insertion direction of the internal channel unit 5 matches the left-right direction. A first insertion hole (not shown) for attaching the water discharge pipe 6 to the internal channel unit 5 from below is formed in the faucet main body 2 near the center in the left-right direction. A second insertion hole 2b for attaching the shower hose 7 to the internal channel unit 5 from behind is formed in the faucet main body 2 near the center in the left-right direction.

A hot water supply pipe 8 is attached from behind via a joint 10 near the left end of the faucet body 2, and a third insertion hole 2c is formed. A first connection member 18 for supplying hot water from the hot water supply pipe 8 is inserted into the third insertion hole 2c. Near the right end of the faucet main body 2, a water supply pipe 9 is attached from behind via a joint 11 to form a fourth insertion hole 2d. A second connection member 19 for supplying water from the water supply pipe 9 is inserted into the fourth insertion hole 2d.

A temperature control handle 3 is attached to the left end of the faucet body 2 . A flow control handle 4 is attached to the right end of the faucet body 2 .

The temperature adjusting handle 3 is rotatably attached to the faucet body 2 . The temperature control handle 3 switches the type of fluid spouted from the spout pipe 6 or the hand shower to water or mixed water depending on the rotational position. Specifically, the temperature adjustment handle 3 switches whether hot water is mixed with cold water. Further, the temperature control handle 3 sets the temperature of the mixed water according to the rotation position when the mixed water is discharged from the discharge pipe 6 or the hand shower.

The flow rate adjusting handle 4 is rotatably attached to the faucet body 2 . The flow rate adjusting handle 4 switches the water or mixed water spouting destination to the spouting pipe 6 or the hand shower according to the rotational position. Also, the flow rate adjusting handle 4 adjusts the flow rate of the water or mixed water spouted from the spouting pipe 6 or the hand shower in accordance with the rotational position.

Here, the internal channel unit 5 will be described with reference to FIGS. 3 and 4. FIG. FIG. 4 is an exploded perspective view of part of the internal channel unit 5. FIG.

The internal channel unit 5 is a unit that allows the water supplied from the water supply pipe 9 to flow between the faucet body 2 and the internal channel unit 5 without flowing. That is, the internal channel unit 5 is a unit in which the channel is completed. The internal channel unit 5 includes an internal case 15 , a temperature adjustment mechanism 16 and a flow rate adjustment mechanism 17 .

The inner case 15 accommodates the temperature adjustment mechanism 16 and the flow rate adjustment mechanism 17 . The inner case 15 is formed in a substantially cylindrical shape to match the inner peripheral wall 2 a of the faucet body 2 .

A first insertion hole 15a is formed in the inner case 15 on the left rear side. A first connection member 18 for supplying hot water from the hot water supply pipe 8 is inserted into the first insertion hole 15a. A second insertion hole 15b is formed in the inner case 15 on the rear right side. A second connection member 19 for supplying water from the water supply pipe 9 is inserted into the second insertion hole 15b.

The internal case 15 is formed with an internal flow path 20 through which water, hot water, or mixed water flows. The internal flow path 20 is a flow path through which water or mixed water is discharged from the discharge pipe 6 or the hand shower without allowing water to flow between the internal flow path unit 5 and the faucet main body 2 . The internal channel 20 is configured by a hot water circulation channel 21 , a water circulation channel 22 and a water discharge channel 23 .

Hot water supplied from the hot water supply pipe 8 flows through the hot water flow passage 21 through the first connection member 18 . Hot water flow path 21 is formed by inner case 15 , second support case 36 of temperature adjustment mechanism 16 , valve element 30 of temperature adjustment mechanism 16 , and isolation wall 37 .

Water supplied from the water supply pipe 9 flows through the water flow passage 22 through the second connection member 19 . The water flow channel 22 is composed of a first channel 22a, a second channel 22b, and a third channel 22c.

The first flow path 22 a is formed by the inner case 15 and the support case 42 of the flow rate adjustment mechanism 17 , and water flows in from the second connection member 19 .

The second flow path 22b communicates with the first flow path 22a and the third flow path 22c. The second flow path 22b is formed by a recess 15c formed near the front center of the inner case 15 and a lid 15d covering the recess 15c. A sealing member 60 is provided between the lid portion 15d and the recessed portion 15c.

The lid portion 15 d is pressed by the inner peripheral wall 2 a of the faucet body 2 when the internal flow path unit 5 is inserted into the faucet body 2 . Therefore, even when water flows into the second flow path 22b and the water pressure in the second flow path 22b increases, the forward movement of the lid portion 15d is restricted by the inner peripheral wall 2a. Therefore, water leakage from the second flow path 22b can be prevented.

The second flow path 22b communicates with the first flow path 22a through a first flow hole 15e formed on the right side, and water flows in from the first flow path 22a. Also, the second flow path 22b communicates with the third flow path 22c via the second flow hole 15f formed on the left side, and allows water to flow into the third flow path 22c.

The third flow path 22 c is formed by the inner case 15 , the first support case 35 of the temperature adjustment mechanism 16 , the valve body 30 of the temperature adjustment mechanism 16 and the isolation wall 37 . The third flow path 22c is formed so as to be adjacent to the hot water flow path 21 with the isolation wall 37 therebetween in the left-right direction.

The water discharge channel 23 is formed by a first support case 35, a second support case 36, etc. of the temperature control mechanism 16 radially inward of the inner case 15 relative to the hot water circulation channel 21 and the water circulation channel 22. . The water discharge channel 23 communicates with the third channel 22c of the water circulation channel 22, and water flows in from the third channel 22c.

Also, the water discharge channel 23 can communicate with the hot water circulation channel 21 by moving the valve body 30 of the temperature control mechanism 16 according to the rotation of the temperature control handle 3 . The water discharge channel 23 communicates with the hot water circulation channel 21, and when hot water flows in from the hot water circulation channel 21, the water and the hot water are mixed to generate mixed water.

The water discharge channel 23 can communicate with the water discharge pipe 6 via a first water discharge port (not shown) formed in the inner case 15 near the center in the left-right direction. Also, the water discharge channel 23 can communicate with the shower hose 7 via a second water discharge port 15g formed in the inner case 15 near the center in the left-right direction. The water discharge channel 23 is provided with a switching valve 41 of the flow rate adjustment mechanism 17 that opens and closes the first water discharge port and the second water discharge port 15g.

In addition, sealing members are provided in the members forming the hot water flow path 21, the water flow path 22, and the water discharge flow path 23 so that water and the like do not leak from the flow paths 21-23.

As described above, the internal flow channel unit 5 has the water flow channel 22, and the water supplied from the water supply pipe 9 flows outside the internal flow channel unit 5, specifically, through the internal flow channel unit 5. The water can flow through the water discharge channel 23 without flowing between the faucet main body 2. - 特許庁

The temperature adjustment mechanism 16 includes a valve body 30 , a temperature sensitive spring 31 , a bias spring 32 , a liner 33 and a spindle 34 .

The temperature-sensitive spring 31 is housed in a first support case 35 provided on the center side in the left-right direction. The temperature sensitive spring 31 is provided in the water discharge channel 23 . The temperature-sensitive spring 31 is a spring whose spring constant changes according to temperature, and is made of, for example, a shape memory alloy. The temperature-sensitive spring 31 urges the valve body 30 leftward.

The bias spring 32 is housed in a second support case 36 provided to the left of the first support case 35 . A bias spring 32 is provided in the water discharge channel 23 . The bias spring 32 is a spring whose spring constant is substantially constant with respect to temperature. A bias spring 32 urges the valve body 30 rightward.

The valve body 30 is provided between the first support case 35 and the second support case 36 . The valve body 30 is supported by the inner case 15 via the isolation wall 37 so as to be movable in the left-right direction. The isolation wall 37 isolates the hot water flow path 21 from the third flow path 22c of the water flow path 22 in the left-right direction. A through hole (not shown) penetrating in the left-right direction is formed in the valve body 30, and water and mixed water can be circulated in the left-right direction.

The valve body 30 moves in the lateral direction according to the biasing force of the bias spring 32 and the biasing force of the temperature sensing spring 31 to adjust the state of communication between the hot water flow path 21 and the water discharge path 23 .

Specifically, the valve body 30 moves leftward when the biasing force of the temperature-sensitive spring 31 is greater than the biasing force of the bias spring 32 . When the valve body 30 moves leftward and comes into contact with the second support case 36, communication between the hot water flow path 21 and the water discharge path 23 is cut off. In this case, hot water does not flow into the water discharge channel 23 .

Further, when the biasing force of the bias spring 32 is greater than the biasing force of the temperature sensing spring 31, the valve body 30 moves rightward. For example, when the biasing force of the bias spring 32 increases from a state in which the valve body 30 abuts against the second support case 36 and is separated from the second support case 36, the hot water flow channel 21 and the water discharge channel 23 communicate with each other. do. As a result, hot water flows into the water discharge channel 23 .

When the valve body 30 is separated from the second support case 36, the biasing force of the bias spring 32 and the biasing force of the temperature sensing spring 31 are held in a balanced position. As the distance between the valve body 30 and the second support case 36 increases, the amount of hot water flowing into the water discharge passage 23 increases. Also, the longer the distance between the valve body 30 and the second support case 36, the shorter the distance between the valve body 30 and the first support case 35, and the less water flows into the water discharge passage 23.

A liner 33 abuts the end of the bias spring 32 opposite the valve body 30 and is connected to the temperature control handle 3 via a spindle 34 . The spindle 34 is rotatably supported by the second support case 36 and converts the rotational movement of the temperature control handle 3 into the linear movement of the liner 33 in the horizontal direction. Therefore, the liner 33 moves laterally in accordance with the rotation of the temperature adjustment handle 3 .

In the temperature adjustment mechanism 16 , the liner 33 moves in the horizontal direction in accordance with the rotation position of the temperature adjustment handle 3 , and the position of the left end of the bias spring 32 is changed. Therefore, the temperature adjustment mechanism 16 can change the position of the valve body 30 at which the biasing force of the bias spring 32 and the biasing force of the temperature sensing spring 31 are balanced according to the rotation position of the temperature adjustment handle 3 . Therefore, the temperature adjustment mechanism 16 can adjust the temperature of the mixed water to the set temperature according to the rotation position of the temperature adjustment handle 3 when the mixed water is spouted.

Further, when the mixed water is discharged, for example, when the temperature of the hot water changes and the temperature of the mixed water changes, the temperature sensing spring 31 expands and contracts according to the temperature of the mixed water, the valve body 30 moves in the left and right direction, The balanced position of the valve body 30 is automatically changed. As a result, the amount of hot water and the amount of water flowing into the water discharge passage 23 are adjusted, and the temperature of the mixed water is automatically adjusted.

The flow rate adjustment mechanism 17 includes a rotary shaft 40 and a switching valve 41 . The rotating shaft 40 is rotatably supported by the support case 42 . One end of the rotating shaft 40 is connected to the flow control handle 4 and the other end is connected to the switching valve 41 .

The switching valve 41 is provided in the water discharge flow path 23 . The switching valve 41 has a cylindrical shape with a bottom, and rotates together with the rotation shaft 40 in accordance with the rotation of the flow rate adjusting handle 4 . A communication port 41 a is formed in the switching valve 41 . The switching valve 41 is provided so as to face the first water outlet formed in the inner case 15 and the second water outlet 15g. The switching valve 41 rotates in accordance with the rotation of the flow rate adjusting handle 4 to switch the state of communication between the communication port 41a, the first water outlet, and the second water outlet 15g.

Specifically, when the flow rate adjusting handle 4 is at a predetermined water stop position, the communication port 41a does not communicate with the first water outlet and the second water outlet 15g. Therefore, when the flow rate adjusting handle 4 is at a predetermined water stop position, water or mixed water is not discharged from the water discharge pipe 6 and the hand shower.

When the flow rate adjusting handle 4 rotates backward from the water stop position, for example, the communication port 41a communicates with the second water outlet 15g. As a result, water or mixed water flows into the shower hose 7 from the second water outlet 15g and is discharged from the hand shower.

Further, when the flow rate adjusting handle 4 rotates forward from the water stop position, for example, the communication port 41a communicates with the first water discharge port. As a result, water or mixed water flows into the water discharge pipe 6 from the first water discharge port and is discharged from the water discharge pipe 6 .

The switching valve 41 can change the area of communication between the communication port 41 a and the first or second water outlet 15 g according to the rotational position of the flow rate adjusting handle 4 . That is, the flow rate adjusting mechanism 17 can adjust the flow rate of water or mixed water spouted from the spouting pipe 6 or the hand shower in accordance with the rotational position of the flow rate adjusting handle 4 .

Next, the joint 10 and the first connecting member 18 will be described with reference to FIG. FIG. 5 is an enlarged view of the vicinity of the first connection member 18 in FIG.

The joint 10 is formed in a cylindrical shape and made of a metal member. A joint 10 attaches the hot water pipe 8 to the faucet body 2 . That is, the joint 10 connects the hot water supply pipe 8 and the faucet main body 2 . A first connection member 18 is inserted into the joint 10 .

The joint 10 includes a tubular portion 10a and a nut 10b. The cylindrical portion 10 a is provided so as to surround the third insertion hole 2 c of the faucet body 2 , is welded to the faucet body 2 , and is attached to the faucet body 2 . The tubular portion 10a protrudes rearward from the faucet body 2 .

The nut 10b is provided on the outer periphery of the tubular portion 10a and fastens the tubular portion 10a and the hot water pipe 8 together. In the joint 10, movement of the nut 10b in the radial direction, that is, in the plane direction orthogonal to the front-rear direction is allowed. As a result, even when the positions of the hot water supply pipe 8 and the tubular portion 10a are displaced in the plane direction perpendicular to the front-rear direction, the tubular portion 10a and the hot water supply pipe 8 can be fastened with the nut 10b.

Note that the shape of the joint 10 is not limited to a cylindrical shape. For example, the joint 10 may have a rectangular tubular shape for a part of the tubular portion 10a.

The first connecting member 18 is a heat insulating member having a smaller thermal conductivity than the metal members such as the faucet body 2 and the joint 10 . The first connection member 18 is made of resin, for example. The first connection member 18 connects the hot water supply pipe 8 and the internal flow path unit 5 , allows hot water to flow from the rear to the front, and allows the hot water to flow from the hot water supply pipe 8 into the hot water circulation flow path 21 . By configuring the first connecting member 18 with a heat insulating member, it is possible to suppress the temperature rise of the joint 10 and to suppress the heat transfer to the faucet main body 2 . Therefore, it is possible to suppress the temperature rise of the faucet body 2, which is likely to be touched by the user.

The first connecting member 18 is inserted into the internal channel unit 5 from a direction intersecting the left-right direction. Specifically, the first connecting member 18 is inserted into the internal channel unit 5 from the rear. The first connection member 18 constitutes an insertion member. By inserting the first connection member 18 into the internal flow path unit 5 in a direction that intersects the left-right direction, the position of the internal flow path unit 5 with respect to the faucet main body 2 can be fixed when the water discharging device 1 is assembled. , and the assemblability of the water discharging device 1 can be improved. Moreover, the position of the internal flow path unit 5 with respect to the faucet main body 2 can be fixed using a part of the water discharging device 1 .

The first connection member 18 includes a main body portion 50 , an insertion portion 51 , a reduced diameter portion 52 , a stopper 53 and a flange 54 .

The body portion 50 is formed in a cylindrical shape, and a check valve 55 is provided inside. The check valve 55 allows hot water to flow from the hot water supply pipe 8 to the hot water flow channel 21 and prohibits hot water to flow from the first flow channel 22a to the hot water supply pipe 8 .

The insertion portion 51 is formed in a cylindrical shape and has a diameter smaller than that of the main body portion 50 . The insertion portion 51 is inserted into the first insertion hole 15 a formed in the internal case 15 of the internal channel unit 5 . A seal member 61 is provided on the outer periphery of the insertion portion 51 . Between the main body portion 50 and the insertion portion 51, a diameter-reduced portion 52 is formed, the diameter of which decreases toward the insertion portion 51 side.

The stopper 53 protrudes leftward from the front end of the reduced diameter portion 52 . The stopper 53 is held between the holding member 62 inserted into the faucet main body 2 from the left and the inner case 15 to prevent the first connecting member 18 from coming off rearward.

The flange 54 protrudes from the rear end of the body portion 50 toward the radially outer side of the body portion 50 , that is, toward the joint 10 . The flange 54 is formed around the entire circumference of the body portion 50 . A seal member 63 is provided between the flange 54 and the hot water pipe 8 . The surface of the flange 54 on the hot water supply pipe 8 side, ie, the rear surface, contacts the seal member 63 , and the surface on the faucet main body 2 side, ie, the front surface, contacts the cylindrical portion 10 a of the joint 10 .

The flange 54 is sandwiched between the hot water supply pipe 8 and the cylindrical portion 10a of the joint 10 via the sealing member 63 when the hot water supply pipe 8 and the faucet main body 2 are connected by the joint 10 . As a result, forward movement of the first connecting member 18 is restricted by the tubular portion 10 a of the joint 10 . Therefore, it is possible to suppress the generation of forward pushing force on the main body portion 50 of the first connection member 18 and the insertion portion 51, and to suppress the deformation of the main body portion 50 and the internal flow path unit 5. can.

In addition, the flange 54 can secure a margin for crushing the sealing member 63, and can prevent hot water from leaking.

As described above, the joint 10 is configured to fasten the tubular portion 10a and the hot water supply pipe 8 even when the positions of the tubular portion 10a and the hot water supply pipe 8 are deviated in the plane direction orthogonal to the front-rear direction. It is Therefore, the positions of the flange 54 and the hot water supply pipe 8 may shift in the plane direction perpendicular to the front-rear direction. Even in such a case, leakage of hot water can be prevented by sandwiching the seal member 63 between the flange 54 and the hot water supply pipe 8 in the front-rear direction.

That is, the sealing member 63 is provided between the surface of the flange 54 orthogonal to the front-rear direction and the surface of the front end of the hot water supply pipe 8, and allows displacement in the surface direction orthogonal to the front-rear direction, which is the flow direction of the hot water. It is a face seal that

In the joint 10 and the first connection member 18, between the main body portion 50 of the first connection member 18 and the cylindrical portion 10a of the joint 10, a surface direction perpendicular to the flow direction of hot water in the first connection member 18, That is, a first predetermined gap is formed in the radial direction of the body portion 50 (the radial direction of the joint 10). A second predetermined gap larger than the first predetermined gap is formed between the flange 54 of the first connecting member 18 and the nut 10b of the joint 10 in the radial direction of the body portion 50 . The first predetermined gap and the second predetermined gap are larger than the dimensional tolerance of the first connecting member 18 and the joint 10 and the installation error that occurs when the tubular portion 10a of the joint 10 is welded to the faucet main body 2.

As a result, even if there is a dimensional tolerance of the first connection member 18 or the joint 10, or an installation error that occurs when the cylindrical portion 10a of the joint 10 is welded to the faucet main body 2, the first connection member can be attached to the joint 10. 18 can be inserted to attach the first connecting member 18 to the internal channel unit 5 .

Even if an installation error occurs, the sealing member 63 can prevent hot water from leaking.

Further, by providing the first predetermined gap and the second predetermined gap, heat transfer to the faucet body 2 can be suppressed, and temperature rise of the faucet body 2 can be suppressed.

The second connection member 19 has the same configuration as the first connection member 18, and detailed description thereof will be omitted. The stopper 53 of the second connection member 19 protrudes rightward. By configuring the second connection member 19 to have the same configuration as the first connection member 18 , the same member can be used as the first connection member 18 and the second connection member 19 . In addition, the second connection member 19 may be configured by, for example, a metal member instead of the heat insulating member.

In a water discharging device according to a comparative example that does not have the internal channel unit 5 of the above embodiment, for example, a channel through which water flows is formed between the faucet main body and the channel unit. Then, in the water discharger according to the comparative example, the water that has flowed between the faucet main body and the channel unit is made to flow into the channel unit.

However, in the water discharger according to the comparative example, there is a possibility that lead may be eluted from the water faucet body and the like into the water to be discharged.

Further, in the water discharger according to the comparative example, a seal member is provided between the faucet main body and the flow channel unit so that water does not leak from the flow channel formed between the faucet main body and the flow channel unit. In the water discharging device according to the comparative example, in order to improve the insertability of the channel unit into the faucet body, for example, the seal member and the channel unit are inserted into the faucet body in a state where the sealing member is compressed and frozen. ing.

However, the water discharger according to the comparative example requires a device for compressing and freezing the seal member, and the cost is increased.

In contrast, the water discharging device 1 according to the embodiment can suppress the elution of lead by using the internal flow path unit 5 . Moreover, the water discharging device 1 according to the embodiment can easily insert the internal flow path unit 5 into the faucet main body 2, and can suppress the cost.

Moreover, the water discharger 1 according to the embodiment includes the first connection member 18 that is inserted into the internal flow path unit 5 from a direction that intersects the horizontal direction, which is the insertion direction of the internal flow path unit 5 . Thereby, the position of the internal channel unit 5 with respect to the faucet main body 2 can be fixed. Therefore, when assembling the water discharging device 1 , lateral movement of the internal flow path unit 5 with respect to the faucet body 2 and rotation of the internal flow path unit 5 with respect to the faucet body 2 can be suppressed. Therefore, the water discharger 1 can improve the ease of assembly.

Further, in the water discharging device 1 according to the embodiment, for example, the first connection member 18 for allowing hot water to flow into the hot water circulation channel 21 is inserted into the internal channel unit 5 . As a result, when assembling the water discharging device 1 , the position of the internal flow path unit 5 can be fixed with respect to the faucet body 2 without using other fixing members that are not a part of the water discharging device 1 .

Further, in the water discharging device 1 according to the embodiment, the position of the internal flow path unit 5 with respect to the faucet main body 2 is changed by inserting the second connection member 19 into the internal flow path unit 5 in addition to the first connection member 18 . It can be fixed more and the assemblability can be improved.

In the water discharger 1 according to the modification, for example, a seal member may be provided between the first connection member 18 and the internal flow path unit 5 to allow displacement in a plane direction perpendicular to the front-rear direction. In this case, for example, the water discharging device 1 according to the modification provides a stepped portion between the main body portion 50 and the insertion portion 51 and provides a sealing member between the stepped portion and the internal flow path unit 5 . As a result, the water discharger 1 according to the modification can prevent hot water from leaking even when the connection position between the first connection member 18 and the hot water supply pipe 8 is displaced in the plane direction perpendicular to the front-rear direction. can.

In this way, the water discharging device 1 is arranged, for example, between the first connection member 18 and the hot water supply pipe 8 and between the first connection member 18 and the internal flow path unit 5 in a plane direction perpendicular to the front-rear direction. A sealing member is provided to allow deviation from the As a result, the water discharger 1 can prevent hot water from leaking even when the connection position between the first connection member 18 and the hot water supply pipe 8 is displaced in the plane direction perpendicular to the front-rear direction.

Moreover, the water discharger 1 according to the modification may use a connecting member of the water supply pipe 9 as a member inserted into the internal flow path unit 5 . This also allows the water discharging device 1 according to the modification to fix the position of the internal flow path unit 5 with respect to the faucet main body 2 when the water discharging device 1 is assembled.

Further effects and modifications can be easily derived by those skilled in the art. Therefore, the broader aspects of the invention are not limited to the specific details and representative embodiments so shown and described. Accordingly, various changes may be made without departing from the spirit or scope of the general inventive concept defined by the appended claims and equivalents thereof.

1 water discharge device 2 faucet main body (outer shell member)
2a inner peripheral wall 5 internal channel unit 10 joint 11 joint 18 first connection member (insertion member)
19 second connection member (insertion member)
20 Internal channel 21 Hot water circulation channel 22 Water circulation channel 23 Water discharge channel

Claims (3)

an internal channel unit in which an internal channel is formed;
an outer shell member into which the internal channel unit is inserted;
an insertion member inserted into the internal channel unit from a direction crossing the insertion direction of the internal channel unit;
a sandwiching member inserted into the outer shell member from the insertion direction with respect to the outer shell member;
with
The insertion member has a stopper formed to protrude from the outer peripheral surface,
The stopper and the holding member are positioned inside the outer shell member and outside the internal flow path unit in the assembled state of the water discharging device,
The water discharging device, wherein the stopper is positioned between the internal flow path unit and the holding member in a direction crossing the insertion direction of the insertion member. The insert member
The water discharging device according to claim 1, wherein the connecting member is a connecting member that allows water or hot water to flow into the internal channel. the internal flow path,
a hot water flow channel for circulating the hot water;
a water circulation channel for circulating the water,
The insert member
a first connection member for allowing the hot water to flow into the hot water circulation channel;
The water discharging device according to claim 2, further comprising: a second connection member that allows the water to flow into the water circulation channel.

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