KR20180043728A - Pressure reducing valve - Google Patents

Abstract

The present invention relates to a pressure-reducing valve which is able to prevent an impact of vibration by ultrasonic fusion when assembling an escape valve, to secure control, and to improve an assembly workability. According to the present invention, the pressure-reducing valve (1) comprises: a valve main frame (10); a valve rod (30); a diaphragm apparatus (40); and an escape valve (50). The escape valve (50) comprises: an escape valve hole (51); a first storage hole (52) communicating with the escape valve hole (51) to store a ball valve body (55) and a valve closure spring (56); and a second storage hole (53a) formed by a penetrating hole of a cylindrical-shaped member (53), whose one end communicates with the first storage hole (52) and whose other end opens a hole on a secondary-side outlet (12). The cylindrical-shaped member (53) is fixated on a mounting hole (58) of the valve main frame (10) by ultrasonic fusion. On an internal wall surface of the side of the secondary-side outlet (12) of the second storage hole (53a) is placed a bump unit (59b). On the outer circumference of a right big hole unit (59) of a spring tray cover (54) is placed a fitting concave unit (59b) to fit the bump unit (53b).

Description

[0001] PRESSURE REDUCING VALVE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a pressure reducing valve used in a hot water supply system or the like, and more particularly, to a pressure reducing valve provided with an escape valve for escaping a primary pressure to a secondary side within a valve body.

As such a pressure-reducing valve, for example, as disclosed in Patent Document 1, there is known a valve body made of resin, a valve stem, and a pressure-reducing movable member (diaphragm device).

Specifically, in the pressure reducing valve disclosed in Patent Document 1, a valve chamber having a valve seat provided therein is provided, an outlet chamber is provided below the valve orifice, and a primary side A valve body made of one member (partial member) provided with an inlet and a secondary outlet connected to the outlet chamber; and a valve body for opening and closing the valve body from the lower side thereof, wherein the valve body is slidable in the up- And a reduced pressure acting member attached to the valve body for driving the valve rod in the up and down direction by detecting the pressure of the secondary side of the outlet side of the secondary side.

In order to protect the valve body and other component parts made of resin, in such a pressure reducing valve, a bypass valve that opens the valve when the pressure on the primary side exceeds a predetermined value and escapes the primary pressure to the secondary side, Respectively. The escape valve includes an escape valve opening that opens into the valve chamber, a lateral hole communicating with the escape valve opening and opening to the outlet of the secondary side, a spring receiving lid fixedly attached to the side end of the lateral hole, And a valve closing spring composed of a ball valve body for opening and closing and a compression coil spring for urging the ball valve body in the valve closing direction.

Patent Document 1: JP-A-2015-210535

However, in the pressure reducing valve disclosed in Patent Document 1, the spring receiving lid is generally fixed to the side end portion of the lateral hole by ultrasonic welding. Specifically, after a ball valve body made of rubber and a valve closing spring are attached to the transverse hole in that order, the spring receiving lid is pressed against the valve closing spring to compress the valve closing spring, As shown in Fig. Therefore, the vibration generated in the ultrasonic welding is transmitted to the valve closing spring or the ball valve body made of rubber via the spring receiving lid, so that the ball valve body is melted or deformed, and is eaten by the valve closing spring. As a result, there is a problem in that the mounting load is reduced due to the inability to obtain the expected length (hereinafter, referred to as the mounting length) of the valve closing spring assumed.

Further, at the time of assembling the escape valve, since it is necessary to fix the spring receiving lid to the side end portion of the lateral hole by ultrasonic welding in opposition to the urging force of the valve closing spring, the state of the spring receiving lid by the repelling force of the valve closing spring There is a problem in that the assembling workability is low.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a pressure reducing valve capable of preventing the influence of vibration due to ultrasonic welding at the time of assembling an escape valve to secure controllability, The purpose.

In order to achieve the above object, a pressure reducing valve according to the present invention is provided with a valve chamber having a valve seat provided therein with an outlet chamber, an outlet chamber provided below the valve orifice, And a secondary side outlet connected to the outlet chamber; a valve stem slidably inserted in the valve body in the up and down direction to open and close the valve hole; And a pressure reducing operating member attached to the valve body for driving the valve rod in the up-and-down direction when the primary pressure of the primary-side inlet is greater than a predetermined value, Wherein the escape valve includes an escape valve opening that opens into the valve chamber, and an escape valve that opens to the escape valve opening And a valve closing spring for urging the valve body in the valve closing direction is accommodated in the receiving hole, the valve body having a receiving hole made of a cylindrical hollow opening to the secondary outlet, And a spring receiving lid for holding the valve closing spring in a compressed state is engaged and fixed by relative rotation with respect to the receiving hole.

In a preferred form, the spring receiving lid is provided with a through hole communicating with the inlet side of the escape valve and the outlet side of the secondary side, or a recessed depressed portion is provided in the end face of the spring receiving lid on the secondary side outlet side .

In a preferred form, at least a part of the through hole or the concave depressed portion has a non-circular shape.

In a preferred form, the spring receiving lid is movable in the axial direction of the receiving hole in the receiving hole, and is rotatable about the axial line of the receiving hole.

Preferably, the receiving hole is provided with a protruding portion for preventing the spring receiving lid from being moved toward the outlet side of the secondary side by the biasing force of the valve closing spring, and the spring receiving lid And an engaging / detaching portion engaged with the protrusion is provided on the outer periphery.

In addition, as a preferred form, an escape groove is provided on the outer periphery of the spring receiving lid for avoiding interference with the protruding portion when the spring receiving lid is inserted into the receiving hole.

In another preferred embodiment, a plurality of the engaging recesses and the escape grooves in the protruding portion and the spring receiving lid in the receiving hole are provided, respectively.

In another preferred form, the protruding portion in the receiving hole and the engaging recess portion and the escape groove in the spring receiving lid are provided at equal intervals, respectively.

In another preferred form, the spring receiving lid is provided with a rotation restricting portion for restricting the rotation of the spring receiving lid in the receiving hole in contact with the projecting portion in accordance with the rotation of the spring receiving lid in the receiving hole.

In another preferred form, the spring receiving lid is provided with an air escaping passage connected to the engaging recessed portion on the outer periphery of the spring receiving lid with the inner plate being turned on the receiving hole.

In another preferred embodiment, the accommodating hole has a first accommodating hole formed of a cylindrical empty hole communicating with the escape valve opening, and a second accommodating hole having a larger diameter than the first accommodating hole with an opening formed in the secondary side outlet .

In a more preferred form, a stepped portion formed between the first receiving hole and the second receiving hole is a stopper portion for stopping the movement of the spring receiving lid toward the entrance of the escape valve.

In a more preferred form, the spring receiving lid has one end small-diameter portion having a size to be inserted into the first receiving hole, and another large-diameter side portion having a larger diameter than the first receiving hole, wherein the one- Is brought into contact with the stopper portion of the receiving hole.

In a more preferable form, the spring receiving lid is rotatable in the receiving hole in a state in which the one end small diameter portion is inserted into the first receiving hole, against the urging force of the valve closing spring.

In a more preferred form, the other-end large-diameter portion is made to be inscribed in the second receiving hole.

In a more preferable form, the tubular member provided with the protruding portion is fixed to the mounting hole provided in the valve body with a through-hole for forming the second receiving hole.

In a more preferred form, the tubular member is fixed to the mounting hole of the valve body by ultrasonic welding.

According to the pressure reducing valve of the present invention, the valve body for opening and closing the escape valve orifice and the accommodating hole for accommodating the valve closing spring for urging the valve body in the valve closing direction are compressed, and the valve closing spring is compressed It is not necessary to fix the spring receiving lid to the end of the receiving hole on the side of the secondary side outlet by the ultrasonic welding as in the conventional case. Therefore, the influence of the vibration due to ultrasonic welding at the time of assembling the escape valve can be prevented, and the mounting length of the valve closing spring can be obtained, thereby ensuring controllability. Further, in assembling the escape valve, for example, after the valve and the valve closing spring are inserted into the receiving hole, the spring receiving lid is inserted into the receiving hole and can be engaged and fixed to the receiving hole by rotation. Can be easily assembled, and the assembling workability can be easily improved.

In addition, since the spring receiving lid is provided with the through hole communicating with the entrance side of the bypass valve and the outlet side of the secondary side, or the recessed depressed portion is provided in the end surface of the outlet side of the secondary side of the spring receiving lid, The spring receiving lid can be rotated through the depression on the side of the secondary side outlet. In addition, when at least a part of the through hole or the concave depressed portion has a non-circular cross section, the spring receiving lid can be easily rotated.

In addition, the receiving hole is provided with a protruding portion for preventing the movement of the spring receiving lid to the outlet side of the secondary side by the urging force of the valve closing spring, and the engaging portion which is engaged with the protruding portion on the outer periphery of the outlet side of the secondary side in the spring receiving lid The spring receiving lid can be easily fixed to the receiving hole by using the engaging structure including the protruding portion and the engaging depressed portion.

In addition, since the spring receiving lid is provided with the rotation restricting portion for restricting the rotation of the spring receiving lid in contact with the protruding portion in accordance with the rotation of the spring receiving lid in the receiving hole, It is possible to easily position the spring receiving lid with respect to the hole, that is, to position the protruding portion and the engagement depressed portion easily.

The first accommodating hole has a receiving hole formed in a cylindrical hollow portion communicating with the escape valve orifice. The second accommodating hole has a larger diameter than that of the first accommodating hole. Since the stepped portion formed between the spring receiving lid and the receiving hole prevents the movement of the spring receiving lid toward the entrance of the escape valve, when the spring receiving lid is inserted into the receiving hole, The insertion into the valve inlet side is blocked, so that the assembling work can be performed more easily.

Further, since the tubular member provided with the protruding portion is fixed to the mounting hole provided in the valve body with the through hole for forming the second receiving hole, the tubular member is separately processed and fixed to the mounting hole, And it becomes possible to integrate them into the main body. Therefore, compared with the case where the protruding portion is provided directly on the valve body, for example, the processability of the protruding portion can be improved, and the variation as a product can be increased.

1 is a sectional view showing a pressure reducing valve according to an embodiment;
Fig. 2 is an enlarged cross-sectional view showing the portion of the escape valve in Fig. 1; Fig.
3 is an exploded perspective view showing the escape valve portion;
4 is a perspective view showing a tubular member;
5 is a perspective view showing a spring receiving lid.
Fig. 6 (a) is a partial side view showing the assembling procedure of the escape valve, and Fig. 6 (b) is a partial cross-sectional view showing the assembling procedure of the escape valve.
FIG. 7A is a partial side view showing the assembling procedure of the escape valve, and FIG. 7B is a partial cross-sectional view showing the assembling procedure of the escape valve.
FIG. 8A is a partial side view showing the assembling procedure of the escape valve, and FIG. 8B is a partial cross-sectional view showing the assembling procedure of the escape valve.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of a pressure reducing valve according to the present invention will be described with reference to the drawings. In the following description, descriptions (positions) and directions (positions) and directions (directions) of up and down, right and left, front and rear are attached for convenience of illustration in order to avoid complicated explanation. It is not pointing.

1 is a sectional view showing a pressure reducing valve according to an embodiment. The pressure reducing valve 1 of the present embodiment is used for a hot water supply facility or the like and mainly includes a valve body 10, a valve stem 30 accommodated in the valve body 10, And a diaphragm device (40).

The valve body 10 is made of, for example, a resin material and is provided therein with a cylindrical valve chamber 21 having a valve seat 23 provided with a valve orifice 22, An outflow chamber 26 is provided. The valve body 10 has an upper surface opening 10a opened to be connected to the valve chamber 21 and a lower opening 10b opened to be connected to the outlet chamber 26. The lower surface opening 10b has a thicker And is blocked by the bottom cover member 60 shaped like a disk. The upper surface opening 10a is closed by the diaphragm device 40.

A primary inlet 11 connected to the valve chamber 21 and a secondary outlet 12 connected to the outlet chamber 26 are formed in the lateral direction on the outer peripheral portion of the valve body 10. The valve chamber 21, the primary inlet 11, the outlet chamber 26 and the secondary outlet 12 are juxtaposed in the transverse direction (i.e., in the horizontal direction) At a predetermined distance from the center of gravity. In other words, the primary inlet 11 and the secondary outlet 12 are not coaxially arranged in the longitudinal direction. A stepped portion 13 constituting a part of the valve seat 23 provided with the valve orifice 22 described above is formed between the valve chamber 21 and the secondary outlet 12. Even if the primary inlet 11 and the secondary outlet 12 are coaxially arranged in the longitudinal direction, the step 13 can be formed by changing the internal shape of the valve body 10 .

A guide hole 19 extending in the vertical direction is formed between the upper surface opening 10a of the valve body 10 and the valve chamber 21 in order to hold the valve stem 30 therebetween. The valve rod 30 is slidably inserted in the guide hole 19 along the vertical direction to open and close the valve hole 22 from the lower side (that is, the side of the outlet chamber 26). The valve stem 30 mainly includes a valve stem 38 slidably inserted in the guide hole 19 of the valve body 10 and inserted into the valve stem 22, And a valve body portion 35 for opening and closing the valve body 22 from the lower side thereof.

The valve shaft 38 includes a diaphragm support portion 32 for supporting the diaphragm device 40 in order from the upper side, a slide radius portion 33 slidably inserted into the guide hole 19, And a thread member 35a (which will be described later) of the valve body portion 35 is provided from the outer periphery of the substantially middle portion of the insertion small diameter portion 34 to the outflow chamber 26, And a conical upper pressing portion 36 for pressing the upper pressing portion 36 from above. A through hole 31 extending in the vertical direction is formed at the center of the valve shaft 38. Female threaded portions 31a and 31b are screwed into the peripheral wall of the upper and lower ends of the through hole 31, respectively. An O-ring 28 is mounted in an annular groove provided on the outer periphery of the slide large-diameter portion 33 so as to be interposed between sliding surface openings formed between the guide hole 19 and the annular groove.

The valve body portion 35 is attached to the outer periphery of the lower end portion of the insertion small diameter portion 34 and has a substantially truncated cone shape extruded at the lower end portion of the insertion small diameter portion 34, And a cylindrical lower pressing member 35b which is fixed to the bottom of the insertion small diameter portion 34 and has a bottom which presses the seal member 35a downward and on the outer periphery. The seal member 35a is fastened with a fastening screw 27 screwed to the female threaded portion 31b provided at the lower end of the through hole 31 so as to be held by the upper pushing portion 36 and the lower pushing member 35b, As shown in Fig. The seal member 35a is formed of, for example, rubber, and the valve seat 22 is opened or closed by its outer circumferential surface being brought into contact with the valve seat 23.

The diaphragm device 40 is attached to an upper portion of the valve body 10 so as to cover the upper surface opening 10a of the valve body 10 in order to sense the pressure on the secondary side of the secondary side outlet 12 and drive the valve rod 30 in the vertical direction .

More specifically, the diaphragm device 40 includes a diaphragm 41 disposed so as to cover an upper surface opening 10a of the valve body 10, and an outer peripheral portion of the diaphragm 41, A cap 42 in the form of a bell with a cross-sectional outline for cooperating with the lower end surface portion 42b in cooperation with the lower end surface portion 42c of the diaphragm 41 and the cap 42, A compression coil spring 45 disposed between the compression coil 42 and the diaphragm 41 for biasing the diaphragm 41 downward and an insertion hole 43a through which a fastening screw 29 screwed to the female threaded portion 31a is inserted, The diaphragm 41 is supported on the inner periphery of the diaphragm 41 to receive the lower end of the spring 45 and the diaphragm 41 is supported in cooperation with the diaphragm support portion 32 of the valve stem 30, A lower spring receiving member 43 in the shape of a hat and a receiving portion 43 for receiving the upper end of the compression coil spring 45, An upper spring receiving member 46 having a substantially elliptical cross section with the tip 46a projecting outward from the upper end and a lower spring receiving member 46 having a lower end in contact with the upper spring receiving member 46, And an adjusting screw 47 provided with a hexagonal hole in a cylindrical shape. The diaphragm device 40 is fixed to the valve body 10 by fastening the lower end face portion 42b of the cap 42 to the diaphragm receiving portion 10c of the valve body 10 with a plurality of bolts It is assembled.

In the diaphragm device 40, a female screw portion 42c is formed on the inner periphery of the upper bulb portion (upper mouth tube portion) 42a of the cap 42 to provide a set load control of the compression coil spring 45 And a male threaded portion 47a provided on the outer periphery of the female threaded portion 42c and the adjustment screw 47 provided with a hexagonal hole are screwed. The set load of the compression coil spring 45 shrunk between the lower spring receiving member 43 and the upper spring receiving member 46 is adjusted by rotating the adjusting screw 47. [ Thereby, the pressure at the time of valve opening of the diaphragm device 40 is regulated.

A pressure reducing chamber (24) is defined between the diaphragm (41) and the upper surface of the diaphragm support portion (32) of the valve shaft (38). Although not shown, the pressure-reducing chamber 24 is provided on the main body portion of the valve body 10 on the side of the secondary-side outlet 12 so as to avoid interference with the escape valve 50, A pressure reducing passage formed of a longitudinal hole is formed. The secondary pressure of the secondary side outlet 12 is sensed by the diaphragm device 40 as the reduced pressure acting member through the pressure reducing passage and the pressure reducing chamber 24 so that the valve connected to the diaphragm 41 of the diaphragm device 40 The rod 30 is driven in the vertical direction within the valve body 10. [

The bottom cover member 60 that closes the bottom opening 10b of the valve body 10 from below has a disk-like base portion 61. The bottom cover member 60 has a base portion 61, Shaped concave portion 63 is provided in order to avoid interference with the tightening screw 27 fastened to the lower end of the valve shaft 38 of the base portion 38 And a stopper portion 62 of a substantially ring shape is provided on the upper surface. In addition, an O-ring 64 as an actual body is mounted in an annular groove provided on the outer periphery of the base 61.

The base 61 of the bottom cover member 60 is fastened and fixed to the valve body 10 by a plurality of bolts 65. The stopper portion 62 provided in the base portion 61 has a structure for restricting the downward movement of the valve rod 30. When the valve rod 30 is lowered by opening the valve hole 22, The lower pressing member 35b of the valve body portion 35 is in contact with the stopper portion 62 so that the valve stem 30 can not be further lowered. In order to prevent the valve plate 30 from sticking to the lower pressing member 35b of the valve plate 30, the stopper portion 62 is provided with a plurality of notches (in the illustrated example, A notch at four positions in the front, rear, and right and left).

In order to protect the valve body 10 made of resin and other constituent components from abnormal high pressures in the pressure reducing valve 1 of the present embodiment, the pressure in the primary side is set to a predetermined value (the internal pressure of the valve body 10, The limit valve 50 is provided at the stepped portion 13 when the flow rate exceeds the limit value.

Fig. 2 is an enlarged sectional view showing the portion of the escape valve in Fig. 1, and Fig. 3 is an exploded perspective view showing the escape valve portion. The escape valve 50 communicates with an escape valve orifice 51 composed of an orifice opening in the valve chamber 21 and its escape valve orifice 51 in order from the left as shown in Figs. 2 and 3, And a receiving hole 57 made of a cylindrical hollow having an opening at the outlet 12. The receiving hole 57 also has a first receiving hole 52 made of a cylindrical hollow that communicates with the escape valve hole 51 and a first receiving hole 52 having an opening at the secondary outlet 12, And a second receiving hole 53a having a larger diameter. The escape valve port 51, the first receiving hole 52, and the second receiving hole 53a are formed in the lateral direction, and are arranged coaxially with each other with a step from the left to the right.

Specifically, the first receiving hole 52 is formed so as to have an inner diameter larger than that of the escape valve orifice 51, and a ball-shaped valve body made of rubber (hereinafter referred to as a ball (Hereinafter referred to as a valve body) 55 and a valve closing spring 56 composed of a compression coil spring for urging the ball valve body 55 in the valve closing direction. The second receiving hole 53a having a larger diameter than the first receiving hole 52 is a cylindrical member fixed to the mounting hole 58 provided on the secondary outlet 12 side of the first receiving hole 52, (Cylindrical member) 53, one end of which communicates with the first receiving hole 52, and the other end of which opens into the secondary outlet 12.

More specifically, the stepped portion 13 of the valve body 10 communicates with the first receiving hole 52 and has a larger diameter than either the first receiving hole 52 or the second receiving hole 53a A mounting hole 58 is provided. An annular groove 58a is formed on the outer periphery of the mounting hole 58 on the side of the lift valve 51 so as to open to the secondary outlet 12 side. A part of the cylindrical member 53 is inserted into the mounting hole 58 and the remaining part of the cylindrical member 53 is exposed to the outside of the mounting hole 58 (the side of the secondary side outlet 12) Which is fixed by ultrasonic welding.

4 is a perspective view showing the cylindrical member. As shown in Figs. 3 and 4, a through-hole for forming the second receiving hole 53a is formed in the center of the inner periphery of the cylindrical member 53. As shown in Fig. The second receiving hole 53a is circular in cross section and has a size that allows the ball valve body 55 and the valve closing spring 56 to be inserted therethrough. The inner wall surface of the end of the second receiving hole 53a on the secondary side outlet 12 side is provided with a pair of projecting portions 53b protruding from the inner wall surface thereof. The pair of protrusions 53b are arranged at intervals of 180 degrees along the circumferential direction of the second receiving hole 53a, that is, arranged so as to face each other.

On the other hand, a ring-shaped bonded portion 53c having an inner diameter larger than the inner diameter of the second receiving hole 53a is provided at the end of the cylindrical member 53 on the side opposite to the end where the protruding portion 53b is formed . The bonded portion 53c is fitted into the annular groove 58a of the mounting hole 58 and the resin material is rapidly melted by the ultrasonic welding so that the stepped portion 13 provided with the mounting hole 58 is bonded do. Thereby, the cylindrical member 53 is integrated with the valve body 10.

2, since the inner diameter of the second receiving hole 53a is larger than that of the first receiving hole 52, the stepped portion 53a is formed between the first receiving hole 52 and the second receiving hole 53a, And the step portion serves as a stopper portion 67 for preventing the movement of the spring receiving lid 54 toward the escape valve opening 51 when the spring receiving lid 54 is inserted into the receiving hole 57 (Described in detail later).

A spring receiving lid 54 for holding the valve closing spring 56 in a compressed state is engaged and fixed in the second receiving hole 53a in the receiving hole 57. [ 5 is a perspective view showing a spring receiving lid. The spring receiving lid 54 is disposed in the receiving hole 57 so as to be movable along the axis O and rotatable about the axis O. [ Specifically, the spring-receiving lid 54 is provided on the left side (on the side of the escape-valve opening 51) of the small diameter portion (that is, slightly smaller in diameter than the first receiving hole 52) to be inserted into the first receiving hole 52 And a large diameter portion 59 on the right side (secondary outlet 12 side) slightly larger in diameter than the first receiving hole 52.

The left small-diameter portion 66 represents a cylindrical shape and has a length of about half the length of the entire spring-receiving lid 54. The left small-diameter portion 66 is inserted into the first receiving hole 52 (described in detail later) while the spring-receiving lid 54 is inserted into the receiving hole 57, The valve closing spring 56 is pressed against the ball valve body 55 and compressed. Due to the difference in outer diameter between the left small-diameter portion 66 and the right large-diameter portion 59, a stepped portion 59g is formed between the both. The stepped portion 59g is brought into contact with the stopper portion 67 formed between the first receiving hole 52 and the second receiving hole 53a.

The right large-diameter portion 59 is integrally formed with the left small-diameter portion 66 and has an outer diameter substantially equal to the inner diameter of the second receiving hole 53a, As shown in FIG. The right large-diameter portion 59 has an escape groove 59a for avoiding interference with the protrusion 53b on the outer periphery thereof in conformity with the shape of the protrusion 53b of the cylindrical member 53 and a protrusion 53b And a plurality of engageable engaging depressions 59b (two in this embodiment) are provided. In the present embodiment, these escape grooves 59a and engaging recesses 59b are alternately arranged at intervals of 90 degrees along the circumferential direction of the second receiving hole 53a.

The escape groove 59a is provided on the outer periphery of the right large-diameter portion 59 of the spring-receiving lid 54 along the direction of insertion into the cylindrical member 53 (i.e., in the direction of the axis O). On the other hand, the engaging recesses 59b extend from the distal end face 59c of the right side large-diameter portion 59 on the side of the secondary side outlet 12 to a predetermined range in accordance with the insertion direction described above (here, Depth).

In order to escape the air inside the second receiving hole 53a and the first receiving hole 52 when the spring receiving lid 54 is inserted into the receiving hole 57, And an air escape groove portion (air escape passage) 59d is provided so as to communicate with the engaging recess portion 59b. This makes it possible to smoothly insert the spring receiving lid 54 into the receiving hole 57 even when the cylindrical member 53 and the spring receiving lid 54 are in close contact with each other.

The right side large-diameter portion 59 of the spring receiving lid 54 comes into contact with the protruding portion 53b of the cylindrical member 53 along with the rotation in the circumferential direction in the receiving hole 57, And a rotation regulating portion 59e for regulating the rotation of the shaft 54 is provided. The rotation regulating portion 59e is located between the adjacent escape groove 59a and the engaging recess 59b and protrudes from the distal end face 59c toward the secondary outlet 12 side. In the present embodiment, only one rotation regulating portion 59e is provided, but two or more rotation regulating portions 59e may be formed as needed. When the engaging recessed portion 59b of the spring receiving lid 54 engages with the protruding portion 53b of the cylindrical member 53, the protruding portion 53b is fitted into the engaging recessed portion 59b, It is not always necessary to provide the rotation regulating portion 59e because the relative rotation between the both can be specified.

A through hole 54a is formed in the center of the inside of the spring receiving lid 54 along the inserting direction (that is, the direction of the axis O) into the cylindrical member 53 (see Fig. 2). The through hole 54a is provided to escape the air inside the first receiving hole 52 or the primary pressure at the time of valve opening to the secondary outlet 12 side. For example, when the above-described air escape groove 59d is provided, the through hole 54a may be omitted.

The portion near the first receiving hole 52 is a small-diameter circular section, and the portion near the secondary-side outlet 12 is a large-diameter sectional non-circular portion 54a. The through hole 54a has a stepped portion, (Non-circular portion). The large-diameter cross section non-circular-shaped portion is a tool insertion hole 59f. The tool insertion hole 59f has a structure for rotating the spring receiving lid 54 and has a cross section on the side of the secondary side outlet 12 of the spring receiving lid 54 ) To about half the length of the through hole 54a. In the present embodiment, the tool insertion hole 59f has a hexagonal section, but it may be a non-circular shape such as a polygonal shape to an elliptical shape other than a hexagonal shape.

By providing the tool insertion hole 59f in this manner, after the spring receiving lid 54 is inserted into the receiving hole 57, the spring receiving lid 54 can be easily rotated by, for example, a hexagonal spanner or the like . In addition, instead of the through hole 54a of the spring receiving lid 54, a concave shaped lid (not pierced) on the distal end face 59c, which is a cross section of the outlet side of the secondary side of the spring receiving lid 54, A pregnant woman may be provided.

The escape valve 50 can be assembled in the order shown in Figs. 6 to 8, for example. The operation of assembling the escape valve 50 is performed by using a dedicated jig or tool, but a jig or a tool is omitted here.

As a preliminary step for assembling the escape valve 50, first, the cylindrical member 53 is integrated with the valve body 10. Concretely, the cylindrical member 53 is inserted (inserted) into the mounting hole 58 so as to fit the welded portion 53c of the cylindrical member 53 into the annular groove 58a, Thereby fixing the image member 53 to the mounting hole 58.

Next, the escape valve 50 is assembled. Concretely, first, the ball valve body 55 and the valve closing spring 56 are successively inserted into the first receiving hole 52 through the second receiving hole 53a (through hole) of the cylindrical member 53, . 6, when the left small-diameter portion 66 of the spring-receiving lid 54 is directed toward the cylindrical member 53, the escape groove 59a and the protruding portion of the cylindrical member 53 The spring receiving lid 54 is inserted into the receiving hole 57 of the cylindrical member 53 while aligning the spring receiving lid 54 and the spring receiving lid 53b.

6 (a), when the spring receiving lid 54 is inserted into the receiving hole 57, since the escape groove 59a is aligned with the protruding portion 53b of the cylindrical member 53, Is inserted without interfering with the projection 53b. The left small-diameter portion 66 of the spring-receiving lid 54 abuts against the distal end portion of the valve-closing spring 56 as it enters the receiving hole 57. At this time, an external force is applied to press the valve closing spring 56 against the biasing force of the valve closing spring 56 so that the left small-diameter portion 66 of the spring- 1 receiving hole 52, and the spring receiving lid 54 is continuously inserted.

The step of inserting the spring receiving lid 54 into the receiving hole 57 is performed so that the stepped portion 59g formed between the left small diameter portion 66 and the right large diameter portion 59 is inserted into the first receiving hole 52 and the second receiving hole 57 And is brought into contact with the stopper portion 67 formed between itself and the receiving hole 53a. The position of the engaging recess 59b of the spring receiving lid 54 in the inserting direction is the same as the position of the engaging recess 59b of the projecting portion 59b of the cylindrical member 53 in the state in which the stepped portion 59g is in contact with the stopper portion 67. [ Is set to be closer to the first receiving hole 52 than the first receiving hole 53b. Therefore, when the left small-diameter portion 66 of the spring receiving lid 54 is inserted into the first receiving hole 52 and the stepped portion 59g contacts the stopper portion 67, the engaging recessed portion 59b And is positioned on the first receiving hole 52 side beyond the position of the projection 53b (see FIG. 7).

Subsequently, as shown by the arrow F in Fig. 7, an external force is applied in the inserting direction and the spring receiving lid 54 is rotated in the counterclockwise direction about 90 degrees as the step portion 59g is brought into contact with the stopper portion 67 Deg. (The side of) the rotation restricting portion 59e of the spring receiving lid 54 comes into contact with (the side surface of) the projecting portion 53b of the cylindrical member 53 with the rotation of the spring receiving lid 54, It is impossible to further rotate the receiving lid 54 further. In this state, when the external force for inserting the spring receiving lid 54 is released, the spring receiving lid 54 is moved in the right direction by the repulsive force of the valve closing spring 56, and the engaging recessed portion 59b The protruding portion 53b is fitted and the engaging recessed portion 59b comes into contact with the protruding portion 53b. This prevents the spring receiving lid 54 from moving toward the secondary outlet 12 due to the repulsive force of the valve closing spring 56. The spring receiving lid 54 is engaged with the cylindrical member 53, (See FIG. 8). As a result, the assembly work of the escape valve 50 is completed. In the case where the escape valve 50 is detached, it may be performed in the reverse order of the above description.

In the escape valve 50 having such a structure, when the primary pressure exceeds a predetermined value, the force in the valve opening direction acting on the ball valve body 55 is applied to the biasing force of the valve closing spring 56 in the valve closing direction The escape valve 50 is opened, and the primary inlet 11 and the secondary outlet 12 communicate with each other. Therefore, the primary pressure is transmitted through the valve chamber 21, the escape valve opening 51, the first receiving hole 52, and the through hole 54a of the spring receiving lid 54 to the secondary outlet 12 side Lt; / RTI > Thereby, the primary side pressure is reduced.

In the pressure reducing valve 1 of the present embodiment, the cylindrical member 53 mounted on the valve body 10 has a second receiving hole 53a through which the ball valve body 55 and the valve closing spring 56 are inserted, And a spring receiving lid 54 for holding the valve closing spring 56 in a compressed state is inserted into the engaging recessed portion 59b provided in the spring receiving lid 54 and the projected portion 53b of the cylindrical shaped member 53, And is fixed to the cylindrical member 53 (that is, the valve body 10) by engagement with the cylindrical member. Specifically, as described above, first, the cylindrical member 53 is fixed to the mounting hole 58 of the valve body 10 by the ultrasonic welding, and the ball valve body 55 and the ball valve body 55 are inserted through the second receiving hole 53a. After the valve closing spring 56 is inserted into the receiving hole 57 (the first receiving hole 52 of the receiving hole 57), the spring receiving lid 54 is inserted into the receiving hole 57 and rotated to form the cylindrical member 53). Therefore, the escape valve 50 can be easily assembled, and the assembling workability can be improved.

Further, since the spring receiving lid 54 is fixed to the valve body 10 (the cylindrical member 53) by the relative rotation with respect to the receiving hole 57 after the spring receiving lid 54 is inserted into the receiving hole 57, It is not necessary to fix the spring receiving lid by ultrasonic welding. As a result, it is possible to prevent the influence of the vibration due to the ultrasonic welding at the time of assembling the escape valve, and it is possible to secure the controllability because the assumed length of the valve closing spring 56 can be obtained.

The protrusion 53b is formed on the inner wall surface of the end of the second receiving hole 53a on the side of the secondary side outlet 12 and the protrusion 53b is formed on the outer periphery of the right large diameter portion 59 of the spring receiving lid 54, The spring receiving lid 54 can be easily attached to the valve body 10 (cylindrical shape) by using the engaging structure composed of the projecting portion 53b and the engaging depressed portion 59b, Phase member 53). As a result, the assembly work of the escape valve 50 can be facilitated compared to the related art.

When the spring receiving lid 54 is inserted into the receiving hole 57, the stepped portion 59g formed between the left small-diameter portion 66 and the right large-diameter portion 59 is inserted into the first receiving hole 52 Of the spring receiving lid 54 and the stopper portion 67 formed between the first receiving hole 53a and the second receiving hole 53a to prevent the insertion of a further layer into the receiving hole 57 of the spring receiving lid 54, Can be easily performed.

The right side large-diameter portion 59 of the spring receiving lid 54 abuts against the projection 53b along with the rotation of the spring receiving lid 54 in the receiving hole 57, The positioning of the spring receiving lid 54 with respect to the receiving hole 57 and the positioning of the protruding portion 53b and the engaging depressed portion 59b can be easily performed because the rotation regulating portion 59e for regulating the rotation is provided .

Since the cylindrical member 53 provided with the protruding portion 53b is fixed to the mounting hole 58 provided in the valve body 10 with the through hole for forming the second receiving hole 53a, It is possible to integrate the cylindrical member 53 into the valve body 10 by fixing the cylindrical member 53 to the mounting hole 58 separately. Therefore, as compared with the case where the protruding portion is provided directly on the valve body, for example, the processability of the protruding portion 53b can be improved, and the variation as a product can be increased.

Although the embodiments of the present invention have been described in detail, the present invention is not limited to the above-described embodiments, and various design changes may be made without departing from the spirit of the present invention described in the claims There is a number.

For example, in the case where the cylindrical member 53 and the spring receiving lid 54 are engaged with and fixed to each other, for example, the inner wall surface of the (second receiving hole 53a) of the receiving hole 57 A protruding portion engageable with the groove may be provided on the outer periphery of the helical groove and the spring receiving lid 54, respectively. It is not necessary to provide the cylindrical member 53. For example, a projecting portion engageable with the engaging recess 59b is formed on the inner wall surface of the end of the first accommodating hole 52 on the secondary side outlet 12 side It may be prepared directly.

1: Reducing valve 10: Valve body
11: Primary inlet 12: Secondary outlet
13: step 21: valve chamber
22: valve seat 23: valve seat
26: outlet chamber 30: valve stem
35: valve body part 36: upper pressing part
37: seal member 38: valve shaft
40: diaphragm device 41: diaphragm
42: cap 43: lower spring receiving member
45: compression coil spring 46: upper spring receiving member
47: adjusting screw 50: escape valve
51: escape valve port 52: first receiving hole
53: Cylindrical member (cylindrical member) 53a: Second receiving hole
53b: projecting portion 53c: welded portion
54: spring receiving lid 54a: through hole
55: ball valve body 56: valve closing spring
57: receiving hole 58: attaching hole
59: Right large-diameter portion 59a: Escape groove
59b: engaging depression part 59c:
59d: air escape groove portion (air escape passage) 59e: rotation restricting portion
59f: tool insertion hole 59g: stepped portion
60: bottom cover member 66: left small-
67: Stopper portion

Claims (17)

A valve chamber having a valve seat with a valve port therein, an outlet chamber provided below the valve port, a primary inlet connected to the valve chamber at an outer periphery thereof, and a secondary outlet connected to the outlet chamber, A valve stem which is vertically slidably inserted into the valve body so as to open and close the valve hole, and a control valve which detects the pressure of the secondary side of the outlet of the secondary side and drives the valve rod in the vertical direction A pressure reducing valve provided with an escape valve for escaping the primary side pressure to the secondary side outlet when the primary side pressure of the primary side inflow port exceeds a predetermined value, as,
Wherein the escape valve has an escape valve opening formed in the valve chamber and a receiving hole communicating with the escape valve opening and formed in a cylindrical hollow opening at the secondary outlet, The valve body and the valve closing spring for urging the valve body in the valve closing direction are accommodated and the spring receiving lid for holding the valve closing spring in the compressed state is engaged and fixed by relative rotation with respect to the receiving hole Features a pressure reducing valve. The method according to claim 1,
Wherein the spring receiving lid is provided with a through hole communicating with the inlet side of the escape valve and the outlet side of the secondary side or a recessed depressed portion is provided in the end face of the spring receiving lid on the secondary side outlet side. Pressure reducing valve. 3. The method of claim 2,
Wherein at least a part of the through hole or the concave depressed portion has a non-circular cross-sectional shape. 4. The method according to any one of claims 1 to 3,
Wherein the spring receiving lid is movable in the axial direction of the receiving hole in the receiving hole and is rotatably disposed about the axis of the receiving hole. 5. The method according to any one of claims 1 to 4,
The spring receiving lid is provided with a protruding portion for preventing movement of the spring receiving lid toward the outlet side of the secondary side by the biasing force of the valve closing spring, And an engaging depressed portion to be engaged with the engaging portion is provided. 6. The method of claim 5,
Wherein an escape groove is provided on an outer periphery of the spring receiving lid to prevent interference with the protruding portion when the spring receiving lid is inserted into the receiving hole. The method according to claim 6,
Wherein a plurality of the engaging recesses and the escape grooves in the protruding portion and the spring receiving lid in the receiving hole are provided, respectively. 8. The method of claim 7,
And the recessed depressed portion and the escape groove in the protruding portion and the spring receiving lid in the receiving hole are provided at equal intervals, respectively. 9. The method according to any one of claims 5 to 8,
Wherein the spring receiving lid is provided with a rotation restricting portion for restricting the rotation of the spring receiving lid in the receiving hole in contact with the projection portion in accordance with the rotation of the spring receiving lid in the receiving hole. . 10. The method according to any one of claims 5 to 9,
Wherein the spring receiving lid is provided with an air escaping passage connected to the engaging recessed portion on an outer periphery of the spring receiving lid with an inner plate being turned on the receiving hole. 11. The method according to any one of claims 5 to 10,
Wherein the accommodating hole has a first accommodating hole formed in a cylindrical hollow space communicating with the escape valve opening and a second accommodating hole opened in the secondary side outlet and having a larger diameter than the first accommodating hole. valve. 12. The method of claim 11,
And a stepped portion formed between the first receiving hole and the second receiving hole serves as a stopper portion for stopping the movement of the spring receiving lid toward the entrance of the escape valve. 13. The method of claim 12,
Wherein the spring receiving lid has one end side small diameter portion which is inserted into the first receiving hole and another end side large diameter portion which is larger in diameter than the first receiving hole and between the one end small diameter portion and the other end side large diameter portion And the formed stepped portion is brought into contact with the stopper portion of the receiving hole. 14. The method of claim 13,
Wherein said spring receiving lid is rotatable in said receiving hole in a state in which said one end small diameter portion is inserted into said first receiving hole against a biasing force of said valve closing spring. The method according to claim 13 or 14,
And the other-end large-diameter portion is made to be inscribed in the second receiving hole. 16. The method according to any one of claims 11 to 15,
Wherein a through hole for forming said second receiving hole is formed in a mounting hole provided in said valve body and a cylindrical member provided with said protruding portion is fixed. 17. The method of claim 16,
Wherein the tubular member is fixed to the mounting hole of the valve body by ultrasonic welding.

Images