KR920008003B1 - Water hammer prevented structure of faucet - Google Patents

Abstract

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Description

Water hammer prevention structure of faucet mechanism

1 to 4 show a first embodiment of the water hemmer preventing structure of the faucet device of the present invention, and FIG. 1 is a longitudinal sectional view.

2 is a cross-sectional view.

3 and 4 are enlarged cross-sectional views of the main portion showing the operating state.

5 to 8 show a second embodiment of the present invention, and Fig. 5 is a longitudinal sectional front view.

6 is a cross-sectional view.

7 and 8 are enlarged cross-sectional views of the main portion showing the operating state.

9 to 12 show a third embodiment of the present invention, and Fig. 9 is a longitudinal sectional front view.

10 is a cross-sectional view.

11 and 12 are enlarged cross-sectional views of the main portion showing the operating state.

13 to 14 show a fourth embodiment of the present invention, and FIG. 13 is a plan view showing a main part across.

6 shows a partially cutaway side view.

* Explanation of symbols for main parts of the drawings

3: escape valve hole 4: escape valve seat

5: spring 6: piston

7: Escape valve body a: Primary side of on-off valve

The present invention relates to a structure for preventing a water hammer caused by suddenly stopping a hot water supply or a water supply in a faucet mechanism, such as a hot water mixing tap or a water tap.

In general, the faucet, regardless of the water or hot water faucet, when the valve is closed rapidly to stop the spout of water or hot water, causes a phenomenon called a water hammer in which the pressure on the primary side rises rapidly. Or damage the device. In particular, in a faucet composed of a fixed disk and a movable disk on which the valve element slides freely, it is easy to cause water hammer since the closing of the valve is performed rapidly when the valve is closed.

The problem to be solved by the present invention is to avoid the rising pressure suddenly generated on the primary side due to the abrupt closing of the valve to the air, and to prevent damage to the pipe or equipment upstream by the rising pressure. Technical means described in the present invention for solving the above problems is to open an escape valve hole for opening the primary side of the on-off valve in the air in the flow passage of the faucet mechanism to the escape valve seat on its perforated edge It is formed on the primary side of the escape valve seat opposite to the escape valve seat, and the force is always added to the escape valve seat by the spring, and when the pressure exceeds the spring force of the spring, the pressure is escaped. It is to exhaust the piston which operates away from the valve seat and the escape valve body which retreats in connection with the piston and hangs on the escape valve seat. Therefore, according to the above technical means of the present invention, when the on-off valve is closed and the pressure on the primary side rises, the piston operates by moving away from the escape valve seat by the rising pressure, and the escape valve body associated with the piston retreats to the escape valve seat. Since the escape valve hole opens away from the valve, the upward pressure on the primary side is discharged into the atmosphere with the escape valve hole described above interposed therebetween.

Embodiments of the present invention will be described below with reference to the drawings. The first embodiment in FIGS. 1 through 4, the second embodiment in FIGS. 5 through 8, the third embodiment in FIGS. 9 through 12, and the FIGS. Each fourth embodiment is shown in the figure. In these embodiments, the faucet mechanism contacts the hot water valve hole 9 and the water supply passage 10 in which the valve element of the on-off valve A contacts the hot water flow passage 8 of the main body 1 before the single-lever type hot water mixing. The fixed disk 14 which drills and installs the mixed-water outflow hole 13 which contact | connects the receiving valve hole 11 and the mixing water flow path 12, and this fixed disk 14 slides freely, The movable disk 16 is formed by concave a passage 15 for contacting the mixing disk 14 and the receiving valve hole 9, 11 to the mixed water outlet hole 13 on the surface in contact with the fixed disk 14. And operate the lever handle 17 to slide the movable disk 16 on the fixed disk 14 to start the flow of the hot water and the water from the hot water passage 8 and the water passage 10 to the mixed water passage 12. At the same time, the rate of inflow into the mixed water flow passage 12 of the bath and water is controlled.

That is, in these embodiments, the hot water flow passage 8 and the water flow passage 10 constitute the primary side a of the on-off valve A, and the mixed water passage 12 constitutes the secondary side b. The mixing channel 12 is open to the atmosphere. Accordingly, in the following description, the primary side a includes both the hot water flow passage 8 and the water flow passage 10. First, the first embodiment shown in FIGS. 1 to 4 will be described with reference to the primary side (a), the primary side (a), the secondary side (b), and the partition wall built on the faucet main body (1). The partition wall 2, which is divided into 2) and divides the primary side (a) and the secondary side (b), has the primary side (a) and the secondary side (b) without the opening / closing valve (A) described above. A through hole 18 to be in contact is installed.

On the other hand, in the faucet main body 1, the open side 19 of the same side as the above-mentioned through-hole 18 is opened, and the escape valve B spreads over the open-side 19 and the through-hole 18. Cylindrical cartridge case 20 is built therein. The cartridge case 20 opens one end and at the other end opens an escape valve hole 3 between the ends and protrudes the escape valve seat 4 on the inner side of the end along the hole edge of the escape valve hole 3. Form.

The cartridge case 20 is provided with an inlet hole 23 in the circumferential surface near the escape valve seat 4, and therein the piston 6, the escape valve body 7, the auxiliary piston 21, and the above. The spring 5 which adds the force to the escape valve seat 4 in the direction of the escape valve seat 4 is accommodated between the auxiliary piston 21 and the piston 6. Then, the cartridge case 20 inserts the primary side a in the main body 1 from the open position 19 in front of the escape valve seat 4 side, and the tip of the cartridge case 20 passes through the partition wall 2. At the same time, seal packing such as an O-ring is fitted therebetween, and the rear open end is closed with a lid (22).

The lid 22 also serves as a lid of the faucet main body 1, and is formed in a cam shape, and is screwed to the cartridge case 20 by the inner circumferential surface thereof, and the opening of the main body 1 by the outer circumferential surface. Screw on (19). As a result, the rear end of the cartridge case 20 is fixed to the opening 19 of the faucet main body 1. In addition, the lid 22 is provided with a ventilation passage 24 which communicates the inside of the cartridge case 20 to the outside of the main body 1. The piston 6 is installed freely by sliding the seal packing with respect to the inner circumferential surface of the cartridge case 20, and the end face facing the escape valve seat 4, i.e., the front face of the escape valve seat 7 ), A concave hole 25 is recessed in the axial direction on the back side, and a small hole 26 communicating in the concave hole 25 is installed on the circumferential surface. The escape valve body 7 constitutes the escape valve B corresponding to the escape valve seat 4, and is integrally provided with the piston 6 by fixing the seat packing on the front surface of the piston 6. The auxiliary piston 21 is installed on the inner circumferential surface of the cartridge case 20 in the rear of the piston 6 so as to slide freely between seal seals, and is located between the piston 6 and the vacancy between the piston 6 ( 27). The spring 5 is elasticized between the auxiliary piston 21 and the lid 22 and escapes the piston 6 between the auxiliary piston 21 and the escape valve body 7 between the piston 6. Add force in the direction of the valve seat (4). Further, in FIG. 1 (D), a bath / shower switching valve installed at the secondary side (b) of the on-off valve, i.e., the mixed water flow passage 12, for selectively switching the supply object of the mixed water to the bath or shower, E) is a valve to stop the water.

In FIG. 2, reference numeral C denotes a check valve, reference numeral 28 denotes a strainer, and the above-mentioned check valve C is also provided in the water passage 10 although not shown in the drawing. When the water in the closed space between the opening / closing valve (A) and the check valve (C) of the water supply passage (10) is heated and largely thermally expands due to the display of the hot water in the flow passage (8) at the time of closing, Since the volume of the sealed space is expanded to absorb the upward pressure, the check valve seat 29 is provided to be movable upstream.

Such a faucet mechanism has a lever handle 17 in an open state of the on / off valve A, that is, hot water or water or both thereof flows from the primary side a to the secondary side b through the on / off valve A. ), The movable disk 16 is slid and moved to stop the closing of the on / off valve A and the flow of fluid from the primary side (a) to the secondary side (b). But the upward pressure acts directly on the piston 6 between the inlet hole 23 of the cartridge case 20. On the other hand, the primary side (a) is in communication with the vacancy 27 formed by the piston (6) and the auxiliary piston 21, but the pressure rise of the primary side (a) because it is a very small hole 26 to communicate with both It takes some time to be delivered into this vacancy 27.

Therefore, when the pressure of the primary side a rises due to the closing valve of the on-off valve A, a difference occurs between the pressure acting on the front surface of the piston 6 and the pressure acting on the rear surface. Retreat against the force of the spring 5 and back to the auxiliary piston (21). Thus, the escape valve body 7 provided on the front surface of the piston 6 also retreats along with the piston 6 and is separated from the escape valve seat 4 so that the escape valve B is modified (FIG. 3). Therefore, the fluid of the primary side (a) flows through the escape valve (B) to the secondary side (b) and is discharged to the atmosphere outside the main body (1), and the pressure of the primary side (a) falls. In other words, the pressure of the primary side (a) which suddenly rises due to the closing valve of the on-off valve (A) causes the escape valve (B) to run to the secondary side (b) soon.

When the pressure on the primary side returns to the positive pressure due to the pressure release to the secondary side b, it moves forward by the force of the spring 6 of the piston 6 and the auxiliary piston 21, and the escape valve body 7 ) Abuts the escape valve seat 4, and the escape valve B closes. In addition, the pressure on the primary side (a) may also increase due to pressure fluctuations in the hot water supply source or the water supply source. In this case, the pressure rises slowly and water flows from the small hole 26 into the vacancy 27. Since there is no pressure difference that can be specifically picked up inside or outside the vacancy 27, the piston 6 does not work and the escape valve B does not change, but if the primary side pressure a exceeds the force of the spring 5, the vacancy ( 27, the auxiliary piston 21 retreats to a position comparable with the pressure of the primary side a and the volume of the vacancy 27 expands (FIG. 4). Thus, due to the increase in the volume of the vacancy 27, the upward pressure of the primary side a is absorbed.

Next, a second embodiment shown in FIGS. 5 to 8 will be described. In this embodiment, an escape valve hole 3 and an escape valve seat 4 are formed directly in the partition 2 partitioning the primary side a and the secondary side b, and the escape valve seat 4 described above. A recessed hole 25 is formed in the back surface of the corresponding escape valve body 7, and the recessed hole 25 is fitted with the piston 6 sliding freely. The piston 6 is in contact with the primary side a so that the cylindrical liner 30 is inserted into the primary side a from the opening 19 formed in the main body 1 coaxially with the escape valve hole 3 described above. Valve body hanger having a diameter smaller than that of the pressure receiving part 31 and the pressure receiving part 31 protruding on the front side of the pressure receiving part 31, the inner peripheral surface of the liner 30 sliding and contacting freely. The fitting 32 and the guide rod 33 protruding from the back of the hydraulic part 31 are integrally formed so that the above-mentioned valve body fitting convex portion 32 is recessed portion 29 of the escape valve body 7. The O oil 34 is slid between them to move freely. Furthermore, the guide rod 33 may be omitted. In addition, the piston 6 pulls both the 6 and 7 apart from the front of the hydraulic part 31 and the rear end face of the escape valve body 7, and adds force to the closing valve body 7 in the closing direction. The second spring 35 is equipped. Therefore, the vacancy 27 is formed between the escape valve body 7 and the piston 6 by the concave hole 25 of the escape valve body 7 and the valve body engagement convex part 32 of the piston 6. Then, a small hole 26 communicating with the vacancy 27 is provided in the side circumferential surface of the escape valve body 7. The liner 30 has a cylindrical shape, and the inner lid 36 is screwed onto the outer circumferential surface opened at one end, and the lid 22 is screwed to the open portion 19 of the main body 1. The screw is attached to the inner circumferential surface and is inserted into the main body 1, and its inner end is opened in the primary side (a) of the on-off valve (A).

And between the said inner lid 36 and the back surface of the piston 6, the strong spring 5 is magnified from the above-mentioned 2nd spring 35. As shown in FIG. In the inner lid 36, a guide hole 37 is opened at the center thereof, and the guide hole 37 is inserted into the guide rod 33 on the rear surface of the piston 6 so as to flow therethrough.

On the other hand, the lid 22 of the main body opening 19 opens a hole for forming a ventilation passage 24 in contact with the guide hole 37 of the inner lid 36 in the liner 30 therebetween. Thus, in the faucet mechanism of the present embodiment, the movable disk 16 is operated by the operation of the lever hand 17 in the open state of the on / off valve A so that the on / off valve A is closed and the pressure on the primary side a is momentarily. If the pressure rises rapidly, the upward pressure immediately acts on the hydraulic part 31 of the piston 6 to retreat the piston 6.

The pressure rise is instantaneous and the contact between the primary side a and the vacancy 27 is made by a very small hole 26. Therefore, there is a slight delay in the action of the pressure on the back of the escape valve body 7. Occurs. Therefore, when the piston 6 retreats due to the delay of the pressure rise in the chamber 27, the piston 6 is attracted to the piston 6, and the escape valve body 7 also retreats with the piston 6, and the escape valve B is modified. (Figure 7). For this reason, the upward pressure of the primary side a is discharged to the secondary side b through the escape valve hole 3, and the pressure of the primary side a immediately falls. Further, due to the pressure drop on the primary side a, the piston 6 returns to the initial position by the force of the spring 5 and returns to the closed position by the force of the second spring 35 by the escape valve body 7. do.

Moreover, even if the pressure on the primary side a may rise due to a cause other than the closing of the on-off valve A, when the pressure rises slowly, the rising pressure also acts in the vacancy 27, and the valve body The piston 6 is pushed back to the position parallel to the primary side (a) pressure between the engagement convex part 32, so that the escape valve body 7 also extends to the escape valve seat 4 The escape valve B is not modified (FIG. 8).

Next, a third embodiment shown in FIGS. 9 to 12 will be described. In this embodiment, the auxiliary piston 21 slides with respect to the concave hole 25 of the piston 6 so as to move freely so that the sheepskin 6, 21 is forced in the opposite direction by the spring 5. At the same time, the vacancy 27 formed by the sheepskin stones 6 and 21 is brought into contact with the secondary side b and the back side of the auxiliary piston 21 is connected to the primary side a. Different from the embodiment. That is, the piston 6 has a slight gap between the lid 22 of the cartridge case 20 and the retreat while the escape valve body 7 installed on the front surface thereof is seated on the escape valve seat 4. Slip the gap to the rear so that the escape valve (B) can be modified, and the bottom part of the concave hole (25) recessed in the axial direction from the rear side is inserted into the bottom part of the non-headed head (41) with a through hole. It protrudes in front of the escape valve body (7). Further, the head portion 41 of the vis 40 with through holes is inserted into the escape valve hole 3 even when the escape valve B is deployed. In addition, the piston 6 forms a smaller outer diameter than the inner diameter of the cartridge case 20 closer to the front than the middle portion.

In the main surface of the cartridge case 20, a small hole 26 is formed at a position corresponding to the small diameter portion of the piston 6 at the rear of the inflow hole 23, and thus the small diameter portion of the piston 6 is formed. And a slight gap formed between the cartridge case 20 constitutes a communication path 42 which guides the water flowing from the small holes 26 into the gap behind the piston 6. Furthermore, the seal packing provided in the outer periphery of the piston 6 is installed in front of the small diameter part. The auxiliary piston 21 slides between seal seals with respect to the inner circumferential surface of the concave hole 25 of the piston 6 so as to move freely, thereby blocking the opening of the concave hole 25 and concave hole 25. The vacancy 27 is formed in the inside. The spring 5 is secured over the bottom of the concave hole 25 of the piston 6 and the front surface of the auxiliary piston 21, and the piston 6 is pressed against the escape valve seat 4 in the direction in which it is pressed. At the same time the force is added to the auxiliary piston 21 in the direction of pressing the lid 23 to the force.

The back surface of the auxiliary piston 21 has a cross groove 42 formed therein, and the force is applied to the spring 5 so that the lid 22 is formed by the back groove 21 even when the lid 22 is pressed against the lid 22. Gap exists between the communication path 42 and the small hole 26 in contact with the primary side A, such as a gap formed between the rear end of the piston 6 and the lid 22. The pressure chamber 44 is formed.

That is, even in the state where the auxiliary piston 21 is pressed against the lid 22, the water introduced into the pressure chamber 44 can enter the rear of the auxiliary piston 21. Thus, in such an embodiment, if the on / off valve A of the faucet mechanism is rapidly closed and the pressure of the primary side a rises rapidly, the upward pressure thereof is the piston 6 between the inlet 23 of the cartage case 20. ) And the back of the auxiliary piston 21 as a slight time delay between the small hole 26, the communication path 42, and the pressure chamber 44, while acting on the front face of the escape valve body 7). 5) between the back of the piston 6, but at the moment when the pressure of the primary side a rises rapidly due to this time delay, there is a difference in the pressure acting on the front side and the back side of the piston 6, The piston 6 retreats in response to the force of the spring 5.

That is, the escape valve body 7 is separated from the escape valve seat 4, and the escape valve B is opened (FIG. 7), and the fluid of the primary side (a) passes through the escape valve B, and the secondary side (b). The pressure on the primary side (a), which is released and thus rapidly rises, soon flees to the secondary side (b). When the water in the sealed space between the hot water supply source, the water supply source pressure change, or the on-off valve A and the upstream check valve C rises smoothly due to thermal expansion, the piston 6 There is no pressure difference on the front side and the rear side, and the auxiliary piston 21 is driven by the pressure in the pressure chamber 44 even though the pressure on the primary side (a) exceeds the force of the spring (5). The piston 6 is not operated and the escape valve B is not modified (FIG. 12), only to be pushed into the chamber 27 until it is balanced with the vehicle side pressure.

Next, a fourth embodiment shown in FIGS. 13 to 14 will be described. In this embodiment, the above-described working example imparts a water hammer prevention function to the main body 1 of the faucet mechanism, and the water hammer prevention function is integrally attached to the main body 1 to supply the hot water in the main body 1. (8) It differs from each embodiment mentioned above in the point which gives the water supply path 10 to the leg-shaped connection socket 46 which connects the piping 45 of hot water supply and water supply. The socket 46 has a pipe connection 47 and a faucet mechanism connection port 48 on opposite sides of the axial end in opposite directions and communicates these inlets 47 and 48 by a water passage 49. The instrument connection port 48 is connected to the hot water supply port 50 or the water supply port 51 of the faucet mechanism main body 1 and attached to the main body 1 of the faucet mechanism to supply the piping connection 47 with the hot water supply or water supply pipe 45. Connect to Therefore, the water passage 49 constitutes a part of the primary side flow path a of the faucet mechanism.

In the water passage 49, a drainage chamber 52 is partitioned by partition walls 52, and a drainage hole 54 is formed in the drainage chamber 53 in a protruding state in the room of the socket 46. . In the partition wall 52, a through hole 55 is opened and opened in the opening portion 56 and the socket 46 of the same shaft as the through hole 55. And the cartridge case 20 which is equipped with a function for preventing the water hammer over the opening 56 and the through-hole 55 is mounted.

The structure of the functional unit and the accommodation cartridge case 20 is the same as the structure of the functional unit and the cartridge case 20 in the above-described third embodiment. Therefore, for these, the same reference numerals are used in FIG. 13 for the same things as those in the third embodiment, and explanation is omitted.

On the other hand, a drain pipe 57 is connected to the drain hole 54 of the drain chamber 53, and the drain pipe 57 is spouted with a spout attachment hole 58 screwed into the spout attachment hole 58 of the main body 1. A drainage import hole 60 is formed in 50 and connected thereto. Accordingly, the drainage chamber 53 is opened to the atmosphere with the drain pipe 57, the spout connecting fitting 50, and the spout 61 interposed therebetween. Thus, if the pressure on the primary side (a) rises rapidly and the escape valve (B) is opened as described in the third embodiment, the upward pressure on the primary side (a) is escape valve hole (3), drain chamber 53, It usually runs away through the drain hole 54, the drain pipe 57, the spout connecting piece 57, and the spout 61. When the water hammer prevention function is applied to the connecting socket as in this embodiment, The main body of the faucet mechanism can be used as it is.

The present invention has the following advantages because it is the configuration as described above.

(1) If sudden pressure rise occurs on the primary side due to sudden closing of the on / off valve, the escape valve is modified to release the upward pressure on the primary side to the secondary side flow path or spout in the air, thus preventing the occurrence of water hammer. have. Therefore, there is no fear of damaging the upstream piping or equipment by water hammer.

(2) Even if a pressure rise occurs on the primary side due to some factor, when the pressure rises slowly, the escape valve body does not operate and the escape valve does not change, so it is versatile for various static pressures.

Claims (1)

An escape valve hole is developed to open the primary side of the shutoff valve in the air during the flow path of the faucet mechanism, and an escape valve seat is formed at the edge of the opening, and the primary valve side of the escape valve seat is installed opposite to the escape valve seat. By this, the force is always added to the left side of the escape valve and at the same time it receives the pressure in the primary side and when the pressure exceeds the spring force of the spring described above, it moves in conjunction with the piston and the piston that moves away from the escape valve seat, and attaches to the escape valve seat. Water hammer prevention structure of the faucet mechanism characterized by arranging falling escape valve body.

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