KR102604515B1 - Hot and cold water mixing faucet - Google Patents

Abstract

The purpose of the present invention is to provide a hot/cold water mixing faucet that can reduce the number of O-rings and prevent damage to the O-rings.
The mixing faucet mechanism of the hot/cold water mixing faucet includes a resin casing 22, a hot water inlet A formed at the tip of the casing and communicating with the hot water supply port, and a hot water valve seat installed at the hot water inlet of the casing ( 22d), a cold water inlet (B) formed in the housing 4 through which cold water flows, a cold water valve seat 4d installed in the cold water inlet of the housing, and a valve body in contact with the hot water valve seat and the cold water valve seat. (25a), a resin-made control valve body 25 that adjusts the opening degrees of the hot water inlet and the cold water inlet, and is installed between the hot water inlet and the cold water inlet, partitions the hot water inlet and the cold water inlet, and controls It is provided with an O-ring 24 in contact with the valve body, and an actuator 28 arranged with one end in contact with the partition wall 4b and the other end in contact with the control valve body.

Description

Hot and cold water mixing faucet{HOT AND COLD WATER MIXING FAUCET}

The present invention relates to a hot/cold water mixing faucet, and particularly to a hot/cold water mixing faucet having a resin housing.

Conventionally, hot/cold water mixing faucets mix hot water and cold water to produce mixed hot/cold water at a predetermined temperature set by the user, and have been widely used in sanitary equipment for showers, bathtubs, and washbasins.

As a general hot/cold water mixing faucet, for example, as described in Japanese Patent No. 2827806, a hot/cold water mixing faucet device including a thermo cartridge and a housing for accommodating the thermo cartridge is known.

Inside the casing of this thermo cartridge, a hot/cold water mixing mechanism is installed to change the temperature of the mixed hot/cold water by adjusting the mixing ratio of hot/cold water.

Additionally, the housing that accommodates this thermo cartridge is comprised of a double housing of an inner housing made of resin and an outer housing made of resin. And, between the resin-made inner housing and the resin-made outer housing, a hot water side passage and a cold water side passage are provided from the hot water side and cold water side supply pipes to the hot/cold water mixing mechanism of the thermo cartridge. Additionally, a mixed hot and cold water passage is provided from the hot and cold water mixing mechanism to the water discharge outlet.

Additionally, a hot water side passage and a mixed hot/cold water passage are provided between the outer peripheral surface of the thermo cartridge and the inner peripheral surface of the inner housing in which the thermo cartridge is accommodated. In addition, between the hot water side passage and the mixed hot and cold water passage, a first O- is formed between the hot water side passage and the mixed hot and cold water passage to prevent the hot water from the hot water side passage and the mixed hot and cold water passage from mixing with each other. Ring is installed.

Likewise, a second O-ring is installed between the hot water side passage and the cold water side passage to prevent hot water and cold water from mixing with each other.

Additionally, in order to airtighten the inside of the inner housing, a third O-ring is installed between the outer peripheral surface of the thermo cartridge and the inner peripheral surface of the inner housing in which the thermo cartridge is accommodated.

Then, hot water and cold water are supplied from the hot water side passage and the cold water side passage of the housing to the hot/cold water mixing mechanism of the thermo cartridge without mixing with each other. And, the mixed hot and cold water of a predetermined temperature by the hot and cold water mixing mechanism is configured to be discharged from the water discharge port through the mixed hot and cold water passage of the housing.

As described above, in order to prevent hot water, cold water, and mixed hot and cold water from mixing and to keep the inside of the housing containing the thermo cartridge airtight, there are at least 3 spaces between the outer peripheral surface of the thermo cartridge and the inner peripheral surface of the inner housing where the thermo cartridge is accommodated. Two O-rings (1st to 3rd O-rings) are required.

In addition, when assembling a hot/cold water mixing faucet, the first to third O-rings move while brushing against the inner peripheral surface of the inner housing, so the O-rings have a long moving distance (the distance they graze each other is long); In other words, there was a problem in that the O-ring located in the innermost part of the housing was more likely to be damaged.

A hot/cold water mixing faucet device that solves this problem is proposed in Japanese Patent Publication No. 2017-67191. The hot/cold water mixing faucet device described in this Japanese Patent Publication No. 2017-67191 accommodates a thermo cartridge in a housing. Additionally, the casing of the thermo cartridge is provided with a first flange to a third flange that defines the space between the inner surface of the housing and the inner surface of the housing. O-rings are provided on the outer peripheral surfaces of the first to third flanges.

The diameter of this first flange is larger than the diameters of the second flange and the diameter of the third flange, and the diameters of the second flange and the diameter of the third flange are formed to be the same.

Meanwhile, the inner surface of the housing has an inner diameter opposing the first flange, and an inner diameter opposing the second flange and the third flange.

The inner diameter opposing the first flange is formed to have a first diameter equal to or larger than the diameter of the first flange. In addition, the inner diameter opposing the second flange and the third flange is formed to be less than the first diameter, and is formed to have a second diameter greater than or equal to the diameter of the second flange and the diameter of the third flange.

And, the inner surface of the housing is formed sequentially from the thermo cartridge insertion side in the housing into a first inner surface having a first diameter and a second inner surface having a second diameter.

In the hot/cold water mixing faucet device of Japanese Patent Publication No. 2017-67191 configured as described above, when the thermo cartridge is stored in the housing, the second flange and the third flange are formed with small diameters, so that the second flange and the third flange are formed with small diameters. 1 Since the inner surfaces (first diameter) do not rub against each other, damage to the O-ring can be suppressed.

As described above, in the hot/cold water mixing faucet device of Japanese Patent Application Laid-Open No. 2017-67191, the diameter of the second flange of the thermo cartridge and the diameter of the third flange are formed to be the same. Additionally, the inner diameter of the housing facing the second flange and the third flange is configured to be less than the first diameter and have a second diameter greater than or equal to the diameter of the second flange and the diameter of the third flange.

Therefore, when the thermo cartridge is stored in the housing, the O-ring on the third flange disposed in the innermost part of the housing moves while rubbing against the second inner surface (second diameter) of the housing, and there is a risk of damage.

In addition, in order to prevent hot water, cold water, and mixed hot and cold water from mixing and to keep the inside of the housing containing the thermo cartridge airtight, there are at least three O-rings between the outer circumferential surface of the thermo cartridge and the inner circumferential surface of the inner housing containing the thermo cartridge. need.

Therefore, it did not meet the social request to reduce the number of parts and reduce costs.

In order to solve the above problems, the present inventors conducted intensive research on the premise of suppressing damage to the O-ring and reducing the number of O-rings. Then, the present inventors reviewed the configuration of the thermo cartridge and the housing configuration, such as making the housing material of resin and forming a part of the thermo cartridge on the housing side. As a result, a solution was discovered that could solve the above problems, and the present invention was developed.

The present invention was made under the above circumstances, and its purpose is to provide a hot/cold water mixing faucet that can reduce the number of O-rings and prevent damage to the O-rings.

The hot/cold water mixing faucet according to the present invention for solving the above problem includes a hot water supply port, a cold water supply port, a plurality of discharge ports, and mixing hot water supplied from the hot water supply port and cold water supplied from the cold water supply port. A cylindrical housing made of resin having a mixing chamber, a switching chamber for switching the plurality of discharge ports, a partition wall dividing the mixing chamber and the switching chamber, and a communication hole formed on the partition wall and communicating the mixing chamber and the switching chamber; A hot/cold water mixing faucet comprising at least a mixing faucet mechanism accommodated in the housing, wherein the mixing faucet mechanism includes at least a resin casing rotatably supporting a rotating shaft for temperature adjustment, and a distal end of the casing. a hot water inlet communicating with the hot water supply port, a hot water valve seat installed in the hot water inlet of the casing, a cold water inlet through which cold water flows, formed in the housing and axially parallel to the hot water inlet, and the housing. A resin control valve body having a cold water valve seat installed in the cold water inlet, a valve body in contact with the hot water valve seat and the cold water valve seat, and adjusting the opening degrees of the hot water inlet and the cold water inlet, and the hot water inlet and the cold water inlet. An O-ring installed in between, dividing the hot water inlet and the cold water inlet, and in contact with the valve body of the control valve body, one end in contact with the partition wall, and the other end in contact with the control valve body, in the mixing chamber. It is characterized by having an actuator disposed.

In this way, the hot/cold water mixing faucet according to the present invention includes a mixing chamber in which hot water supplied from a hot water supply port and cold water supplied from a cold water supply port are mixed, and a partition wall dividing the mixing chamber and the switching chamber is formed in the housing. Additionally, a communication hole is formed in this partition wall to communicate with the mixing chamber and the conversion chamber, and a cold water valve seat for the cold water inlet is further installed in the housing.

Therefore, the mixed hot and cold water from the mixing chamber and the cold water from the cold water inlet do not mix with each other, and there is no need to install an O-ring as in the past.

That is, in the hot/cold water mixing faucet according to the present invention, an O-ring is installed between the hot water inlet and the cold water inlet, partitions the hot water inlet and the cold water inlet, and is in contact with the valve body of the control valve body. By doing so, it is possible to prevent hot water, cold water, and mixed hot and cold water from mixing with each other.

Here, between the housing end where the casing is inserted and the cold water inlet, an inner peripheral surface of the housing with the minimum diameter is formed between the hot water valve seat and the cold water inlet, and at an end formed on the inner peripheral surface of the housing with the minimum diameter, the O- It is desirable for the ring to be placed.

In this way, when viewed from the end of the housing into which the casing is inserted, the O-ring is disposed at an end formed on the inner peripheral surface of the housing with the minimum diameter formed between the hot water valve seat and the cold water inlet. Therefore, even if the O-ring is received from the housing end side where the casing is inserted, the O-ring does not rub against the inner peripheral surface of the housing, and damage to the O-ring can be prevented.

Additionally, a hot water inflow path is formed between the inner peripheral surface of the housing and the outer peripheral surface of the casing, which communicates with the hot water supply port and also communicates with the hot water inlet. Additionally, the tip of the casing is formed to have a larger diameter than the outer diameter of the casing where the hot water inlet is formed, and the O-ring is disposed between the end provided in the housing and the tip of the casing. This preferably separates the hot water inlet and the cold water inlet.

Because of this configuration, by housing the casing in the housing, a hot water inlet path is formed that communicates with the hot water supply port and also communicates with the hot water inlet, and the O-ring is pressed against the end provided in the housing to connect the hot water inlet and the hot water inlet. The cold water inlet is divided, preventing hot and cold water from mixing with each other.

Additionally, it is preferable that the housing, casing, and control valve body are made of the same resin. When the housing, casing, and control valve body are made of the same resin, wear of the valve and valve seat can be suppressed.

As described above, according to the present invention, it is possible to obtain a hot/cold water mixing faucet that can reduce the number of O-rings and prevent damage to the O-rings.

Figure 1 is a perspective view showing an embodiment of a hot/cold water mixing faucet according to the present invention.
Figure 2 is a front view of the embodiment shown in Figure 1.
Figure 3 is a cross-sectional view taken along line AA of Figure 2.
FIG. 4 is a view showing the control valve body shown in FIG. 3, where (a) is a side view and (b) is a front view.
Figure 5 is an enlarged view of the main portion of the hot water inlet and cold water inlet shown in Figure 3.
Figure 6 is a front view for explaining an example of assembly of a hot/cold water mixing faucet according to the present invention, and is a diagram corresponding to Figure 2.
Figure 7 is a cross-sectional view taken along line AA of Figure 6.
Figure 8 is a front view for explaining another example of assembly of a hot/cold water mixing faucet according to the present invention, and is a diagram corresponding to Figure 2.
Figure 9 is a cross-sectional view taken along line AA of Figure 8.

Hereinafter, a hot/cold water mixing faucet according to an embodiment of the present invention will be described based on FIGS. 1 to 7.

As shown in FIG. 1, the hot/cold water mixing faucet 1 is provided with a housing 4 that accommodates a mixing faucet mechanism 2 for mixing hot and cold water and a discharge switching mechanism 3. This housing 4 is formed in a substantially cylindrical shape, and the mixing faucet mechanism 2 for mixing hot and cold water is located on one side of the housing 4, and the hot and cold water switching mechanism 3 is located on the other side of the housing 4. Accepted on one side.

Additionally, this housing 4 includes a hot water supply port 5 to which a hot water supply pipe for supplying hot water is connected, a cold water supply port 6 to which a cold water supply pipe for supplying cold water is connected, and a discharge pipe (not shown). It is provided with a first outlet (7) for supplying mixed hot and cold water to the shower, and a second outlet (8) to which a shower hose and the like are attached and for supplying mixed hot and cold water to the shower.

The hot water supply port 5 and the cold water supply port 6 are installed on the rear side of the substantially cylindrical housing 4, and the first discharge port 7 is installed on the lower surface side of the substantially cylindrical housing 4. , the second discharge port 8 is installed on the upper surface side of the housing 4.

This housing 4 is made of resin, and as the resin, for example, PPS (polyphenylene sulfide) resin, PSF (polysulfone) resin, etc., which have heat resistance, are used, and the hot water supply port 5, The housing 4, which has a cold water supply port 6, a first discharge port 7, and a second discharge port 8, is formed by molding.

In addition, although not shown in FIGS. 1 to 7, a temperature adjustment dial (lever) for rotating the rotating shaft 21 is installed outside the rotating shaft 21 for operating the mixing water receiving mechanism 2. Similarly, a switching dial (lever) for rotating the rotating shaft 31 is provided outside the rotating shaft 31 for operating the discharge switching mechanism 3.

In addition, as shown in FIG. 3, the discharge switching mechanism 3 includes a switching valve 32 that switches the first discharge port and the second discharge port by rotation of the rotating shaft 31, and a discharge switching switch of the housing 4. It is provided with a cover body (33) that seals the receiving end of the device. Since the discharge switching mechanism 3 has the same configuration as generally known, detailed description is omitted.

Next, the mixing water faucet mechanism 2 will be explained based on FIGS. 3 to 5.

As shown in FIG. 3, the mixing water receiving mechanism 2 has a casing 22 that rotatably supports the rotating shaft 21. This casing 22 is made of resin, and heat-resistant resin such as PPS (polyphenylene sulfide) resin or PSF (polysulfone) resin is used as the resin, and is formed by molding.

As shown in FIGS. 3, 6, and 7, this casing 22 is formed as a cylindrical shape with a bottom as an overall shape, and has a hot water supply port 5 and a hot water supply port 5 on the barrel wall of the distal end of the casing 22. A hot water inlet A is formed, which communicates with each other and allows hot water to flow into the inside of the casing 22. In addition, the hot water supply port 5 and the hot water inlet A are communicated by a hot water inlet path E formed by the inner peripheral surface of the housing 4 and the outer peripheral surface of the casing 22.

In addition, as shown in FIG. 7, the outer diameter D3 of the tip 22c of the casing 22 is formed to be larger than the outer diameter D4 of the casing 22 where the hot water inlet A is formed, and The O-ring 24 is disposed between the end 4f installed on the housing 4 and the tip 22c of the casing 22 (see Fig. 5).

Additionally, an O-ring 23 is provided on the outer peripheral surface of the casing 22 to maintain airtightness between the casing 22 and the housing 4.

In addition, a cover 22a is formed on the outer peripheral surface of the casing 22, and a threaded portion 22b is formed on the outer peripheral surface of the cover 22a, and is configured to be screwed to the threaded portion 4a of the housing 4. do.

Therefore, when the casing 22 (mixed faucet mechanism 2) is accommodated in the housing 4, the inside of the housing 4 is sealed, and leakage of hot and cold water is prevented.

A cold water inlet (B) through which cold water flows is provided axially parallel to the hot water inlet (A) at the distal end of the casing (22). This cold water inlet (B) is formed in the housing (4), and the hot water inlet (A) and the cold water inlet (B) are partitioned by the O-ring 24 and the tip 22c of the casing 22, This is done so that the and cold water do not mix with each other.

In addition, the O-ring 24 is in contact with the valve body 25a of the control valve body described later, and divides the hot water inlet A and the cold water inlet B even when the valve body 25a moves, This is done so that hot and cold water do not mix.

Additionally, a mixing chamber (C) is formed from inside the hot water inlet (A) and cold water inlet (B) of the casing 1 toward the switching chamber D (right side in FIG. 3) of the housing 4.

Additionally, a partition wall 4b is provided in the housing 4, and the partition wall 4b divides the mixing chamber C into the mixing chamber C and the switching chamber D where the discharge switching mechanism 3 is accommodated.

In this partition wall 4b, a communication hole 4c is formed for discharging the mixed hot and cold water into the switching chamber D, and the hot water flowing in from the hot water inlet A and the cold water flowing in from the cold water inlet B are formed. , each flows to the mixing chamber (C), and after the cold water and hot water are mixed in the mixing chamber (C), the mixed hot and cold water is supplied to the switching chamber (D) from the communication hole (4c).

In addition, as shown in FIG. 5, a hot water valve seat 22d is formed at a position on the left side of the hot water inlet (A) of the casing 22, and a hot water valve seat 22d is formed at a position on the right side of the cold water inlet (B) of the housing 4. A cold water valve seat 4d is formed.

And between the hot water valve seat 22d and the cold water valve seat 4d, a control valve element 25 movable in the axial direction of the housing 4 is built.

That is, by the control valve body 25 having the hot water valve 25f and the cold water valve 25g (valve body 25a), which is in contact with the hot water valve seat 22d and the cold water valve seat 4d, the hot water inlet The opening degrees of (A) and cold water inlet (B) are adjusted, and the supply amounts of hot water and cold water to the mixing chamber (C) are adjusted.

In addition, the mixing water faucet mechanism 2 is an adjustment screw shaft that is screw-engaged with the rotary shaft 21, moves forward and backward according to the rotational motion of the rotary shaft 21, and adjusts the axial position of the control valve body 25. (26) is provided.

This adjustment screw shaft 26 is configured to be movable in the axis direction of the casing 22 without rotating around the casing 22 . Additionally, a threaded portion 26a is formed on the adjusting screw shaft 26 and is screwed with the threaded portion 21a of the rotating shaft 21.

As a result, by rotating the temperature control dial, the screw portion 21a of the rotary shaft 21 rotates, causing the adjustment screw shaft 26 to slide in the axial direction, and the control valve body 25 through the deflector 27. Move it.

That is, by operating the temperature control dial, the user can set and change the position of the control valve body 25 so that mixed water at a desired temperature is discharged.

In FIG. 3 , reference numeral 29 denotes a return spring of the adjustment screw shaft 26, one end of which is caught by the fixing member 29a, and the other end of which is caught by the adjustment screw shaft 26. By this return spring 29, the adjustment screw shaft 26 can be moved in the axis direction without rattling.

As shown in FIG. 4, the control valve body 25 includes a valve body 25a formed in a cylindrical shape, and a deflection body accommodating portion formed in a bottomed cylindrical shape provided inside the valve body 25a. (25b), a rib 25c extending in the axial direction for connecting the valve body 25a and the deflector accommodating portion 25b, and an outer side from the bottom portion 25d of the deflector accommodating portion 25b. A shaft portion 25e extending in the axial direction toward is provided.

As shown in FIG. 3, this shaft portion 25e is slidably inserted into the shaft guide hole 4e formed in the partition wall 4b of the housing 4, and allows the movement of the control valve body 25. It is designed to guide you.

Additionally, a communication hole 25h is formed in the bottom portion 25d for guiding hot water entering the inside of the deflector accommodating portion 25b into the mixing chamber C. Additionally, a distribution path 25i is formed between the inner peripheral surface of the valve body 25a and the outer peripheral surface of the deflector accommodating portion 25b (between the ribs 25c) to guide hot water into the mixing chamber C.

In addition, this control valve body 25 is formed by molding from, for example, PPS (polyphenylene sulfide) resin, PSF (polysulfone) resin, etc., which has heat resistance.

In addition, in the valve body 25a, a hot water valve 25f is formed at one edge of the barrel wall (upper edge in Fig. 4(b)), and a cold water valve 25g is formed at the other end edge (lower edge in Fig. 4). is formed.

When the hot water valve 25f of the control valve body 25 comes into contact with the hot water valve seat 22d of the casing 22, the supply of hot water is blocked. Additionally, the cold water valve 25g of the control valve body contacts the cold water valve seat 4d of the housing 4, thereby blocking the supply of cold water.

In this way, the hot water valve 25f of the control valve body 25 is in contact with the hot water valve seat 22d of the casing 22, and the cold water valve 25g of the control valve body is in contact with the cold water valve seat (22d) of the housing 4. Although it is in contact with 4d), since the control valve body 25, casing 22, and housing 4 are made of resin, wear of the valve and valve seat can be suppressed. In particular, it is preferable that the control valve body 25, casing 22, and housing 4 are formed of the same resin.

In addition, as shown in FIGS. 3 and 5, the control valve body 25 is in contact with one O-ring 24, which is installed between the hot water inlet A and the cold water inlet B. It is supported by an O-ring (24).

That is, the outer peripheral surface of the valve body 25a is supported in contact with one O-ring 24, and in addition to making the space between the hot water valve 25f and the cold water valve 25g airtight, the valve body 25a is It is configured to be able to slide in the axis direction. Then, as the valve body 25a slides in the axial direction, the amount of hot water is adjusted by the opening degrees of the hot water valve 25f and the hot water valve seat 22d, as described above, and the cold water valve 25g and the cold water valve The amount of hot water is adjusted depending on the opening degree of the seat 4d.

In addition, as shown in FIGS. 3 and 5, this O-ring 24 is press-welded to the end portion 4f provided on the housing 4 by the tip 22c of the casing 22, thereby forming a hot water inlet. Divide (A) and cold water inlet (B) to prevent leakage of hot and cold water between hot water inlet (A) and cold water inlet (B).

Here, on the inner peripheral surface of the housing between the end of the housing where the casing 22 is inserted and the cold water inlet (B), an inner peripheral surface of the housing with a minimum diameter is formed between the hot water inlet (A) and the cold water inlet (B). Then, an end portion 4f is formed on the inner peripheral surface of the housing of this minimum diameter.

That is, this end 4f is between the end of the housing 4 where the casing 22 is inserted and the cold water inlet B, and is formed on the inner peripheral surface of the housing 4 with the minimum diameter.

Therefore, when this O-ring 24 is placed on the end portion 4f provided in the housing 4, it does not rub against the inner peripheral surface of the housing 4, preventing damage to the O-ring 24. can do.

The material of this O-ring 10 is EPDM (ethylene propylene diene rubber), propylene hexafluoride-vinylidene fluoride copolymer (FKM), or butyl rubber.

This propylene hexafluoride-vinylidene fluoride copolymer (FKM) has the properties of heat resistance, low rebound elasticity, and excellent shock absorption, and like butyl rubber, propylene hexafluoride-vinylidene fluoride copolymer (FKM), It is preferable because it has low heat resistance and rebound elasticity, and has excellent shock absorption properties.

In addition, a deflection element 27 is accommodated inside the deflection element accommodating part 25b of the control valve element 25, and one end of the deflection element 27 is the bottom part 25d of the deflection element accommodating part 25b. It is placed in contact with the inner surface of the.

This allows the control valve body 25 to slide toward the cold water valve seat 4d by receiving the repulsive force of the deflection body 27.

Additionally, one end of the actuator 28 is disposed in contact with the outer surface of the bottom portion 25d of the deflector accommodating portion 25b. As a result, the control valve body 25 can be slid toward the hot water valve seat 22d by receiving the repulsive force of the actuator 28.

Additionally, the deflector 27 is made of a material with a constant spring constant. Examples of this deflector 27 include a coil spring made of stainless steel, but there is no particular limitation on the specific structure.

Additionally, the actuator 28 expands and contracts according to temperature changes. This actuator 28 may include, for example, a shape memory alloy (SMA) spring formed from a material whose spring constant changes depending on temperature, or a wax element. However, the specific configuration may vary. There is no particular limitation on this.

As shown in FIG. 3, this actuator 28 is supported by contacting the partition wall 4b formed inside the housing 4 and the outer surface of the bottom of the control valve body 25.

And, the control valve body 25 maintains the gap between the hot water valve 25f and the hot water valve seat 2d and the cold water valve 25g by balancing the loads received from the deflector 27 and the actuator 28. Adjust the gap between the cold water valve seats (4d).

With this configuration, the hot/cold water mixing faucet 1 adjusts the mixing ratio of hot water flowing in from the hot water inlet A and cold water flowing in from the cold water inlet B.

Next, based on FIGS. 6 and 7, an example of assembly of a hot/cold water mixing faucet will be described.

The actuator 28 is accommodated in the mixing chamber C of the housing 4, and is arranged so that one end is in contact with the partition wall 4b.

Subsequently, the control valve body 25a, in which the O-ring 24 is previously mounted on the outer peripheral surface of the valve body 25 and the deflection body 27 is accommodated in the deflection body accommodating portion 25b, is placed in the housing 4. ) is housed in the mixing room (C).

At this time, the shaft portion 25e of the control valve body 25 is inserted into the shaft guide hole 4e of the partition wall 4b, and the actuator 28 is installed on the outer surface of the bottom portion 25d of the control valve body 25. ) is placed so that the other end is in contact.

In addition, since the outer diameter D1 of the O-ring 24 is formed smaller than the inner diameter D2 of the housing (excluding the end 4f), the control valve body 25 When accommodated, the O-rings 24 move on the inner peripheral surface of the housing 4 without rubbing against each other, and are caught on the end portion 4f.

In addition, since the outer diameter D3 of the tip 22c of the casing is also formed to be smaller than the inner diameter D2 of the housing (excluding the end 4f), when the casing 22 is accommodated, the housing 4 By moving without rubbing against each other on the inner peripheral surface, the O-ring (24) can be pressed.

Then, the casing 22 containing the adjustment screw shaft 26, the rotation shaft 21, etc. is accommodated inside the housing 21.

At this time, the tip 22c of the casing 22 is in contact with the O-ring 24 and divides the hot water inlet A and the cold water inlet B so that the hot water and cold water do not mix with each other.

In addition, since the outer diameter D4 of the casing 22 is formed to be smaller than the inner diameter D2 of the housing 4, the casing 22 is accommodated within the housing 4, thereby forming a bond between the housing 4 and the casing 22. A hot water inflow path (E) is formed between them.

In addition, the O-ring 23 installed on the outer peripheral surface of the casing 22 makes the space between the housing 4 and the casing 22 airtight and prevents leakage of hot and cold water.

Additionally, the casing 22 is fixed to the housing 4 by screwing the cover 22a to the housing 4 and is prevented from falling off.

Next, based on FIGS. 8 and 9, another example of assembly of a hot/cold water mixing faucet will be described.

An example of assembly of this hot/cold water mixing faucet includes, in advance, an adjustment screw shaft 26, a rotation shaft 21, a deflector 27, a control valve body 25, an actuator 28, an O-ring 24, etc. Prepare this built-in casing (22).

Then, the casing 22 is accommodated in the mixing chamber C of the housing 4, and the shaft portion 25e of the control valve body 25 is inserted into the shaft guide hole 4e of the partition wall 4b. In addition, one end of the actuator 28 is in contact with the partition wall 4b (the other end of the actuator 28 is in contact with the outer surface 2 of the bottom 25d of the control valve body 25). (so that) placed.

When accommodating the control valve body 25, the O-rings 24 move on the inner peripheral surface of the housing 4 without rubbing against each other, and are caught on the end portion 4f. As a result, the tip 22c of the casing 22 is in contact with the O-ring 24 and divides the hot water inlet A and the cold water inlet B so that the hot water and cold water do not mix with each other.

Additionally, when the casing 22 is accommodated within the housing 4, a hot water inflow path E is formed. In addition, the O-ring 23 installed on the outer peripheral surface of the casing 22 makes the space between the housing 4 and the casing 22 airtight, preventing leakage of hot and cold water.

Additionally, the casing 22 is fixed to the housing 4 by screwing the cover 22a to the housing 4 and is prevented from falling off.

In the hot/cold water mixing faucet assembled in this way, after setting the temperature at which hot water is produced by adjusting the deflection amount of the deflector 27 using a temperature control handle (not shown), the conventional hot/cold water mixing faucet is used. Similarly, the actuator 28 and the deflector 27 adjust the opening degrees of the hot water inlet and the cold water inlet by the control valve element, thereby adjusting the temperature at which the hot water comes out.

As described above, the hot/cold water mixing faucet according to the present invention does not need to install an O-ring to prevent mixed hot/cold water from the mixing chamber and cold water from the cold water inlet from mixing, and does not require mixing of hot and cold water. When accommodating an O-ring, the O-ring does not rub against the inner peripheral surface of the housing, thereby preventing damage to the O-ring.

In addition, by housing the casing in the housing, a hot water inlet is formed that communicates with the hot water supply port and also communicates with the hot water inlet, and the O-ring is pressed to the end provided in the housing to partition the hot water inlet and the cold water inlet. , can prevent hot and cold water from mixing with each other.

Additionally, when the housing, casing, and control valve body are made of the same resin, wear of the valve and valve seat can be suppressed.

1: Hot/cold water mixing faucet 2: Mixing faucet mechanism
3: Discharge switching mechanism 4: Housing
4a: threaded portion 4b: partition wall
4c: Flue port 4d: Cold water valve seat
4e: axis guide hole 4f: end
5: hot water supply port 6: cold water supply port
7: first outlet 8: second outlet
21: rotating shaft 22: casing
22c: Casing tip 22d: Hot water valve seat
23: O-ring 24: O-ring
25: control valve body 25a: valve body
25f: hot water valve 25g: cold water valve
26: Adjusting screw shaft 27: Deflector
28: Actuator A: Hot water inlet
B: Cold water inlet C: Mixing chamber
D: Conversion room E: Hot water inlet

Claims (5)

A hot water supply port, a cold water supply port, a plurality of discharge ports, a mixing chamber for mixing hot water supplied from the hot water supply port and cold water supplied from the cold water supply port, a switching chamber for switching the plurality of discharge ports, the mixing chamber and the switching chamber hot/cold water, comprising at least a partition wall dividing the partition wall, a resin cylindrical housing formed on the partition wall and having a communication hole for communicating the mixing chamber and the switching chamber, and a mixing faucet mechanism accommodated in the housing. As a mixing faucet,
The mixing faucet mechanism is, at least,
A resin casing that rotatably supports a rotating shaft for temperature adjustment,
a hot water inlet formed at the front end of the casing and communicating with the hot water supply port;
A hot water valve seat installed at the hot water inlet of the casing,
A cold water inlet through which cold water flows, formed in the housing and axially parallel to the hot water inlet,
a cold water valve seat installed at the cold water inlet of the housing and formed on the housing;
A control valve body made of resin, which has a valve body in contact with the hot water valve seat and the cold water valve seat, and adjusts the opening degrees of the hot water inlet and the cold water inlet;
An O-ring installed between the hot water inlet and the cold water inlet, dividing the hot water inlet and the cold water inlet, and contacting the valve body of the control valve body,
An actuator disposed in the mixing chamber, wherein one end is in contact with the partition wall and the other end is in contact with the control valve body.
A hot/cold water mixing faucet comprising a. The hot/cold water mixing faucet according to claim 1, wherein the O-ring is in contact with the housing and the valve body of the control valve body. According to clause 1,
Between the housing end where the casing is inserted and the cold water inlet, a housing inner peripheral surface with a minimum diameter is formed between the hot water valve seat and the cold water inlet,
A hot/cold water mixing faucet, wherein the O-ring is disposed at an end formed on the inner peripheral surface of the housing of the minimum diameter. According to clause 3,
A hot water inlet is formed between the inner peripheral surface of the housing and the outer peripheral surface of the casing, communicating with the hot water supply port and communicating with the hot water inlet,
The tip of the casing is formed to have a larger diameter than the outer diameter of the casing where the hot water inlet is formed,
A hot/cold water mixing faucet, characterized in that the O-ring is disposed between the end installed in the housing and the front end of the casing, thereby dividing the hot water inlet and the cold water inlet. According to any one of claims 1 to 4,
A hot/cold water mixing faucet, wherein the housing, casing, and control valve body are formed of the same resin.

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