JP3696503B2 - Gas pressure reducing valve - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a gas pressure reducing valve, and in particular, to a valve seat in which a peripheral portion of a diaphragm that causes gas pressure in a pressure reducing chamber to act on one side is sandwiched between valve housings, and a valve hole leading to the pressure reducing chamber is opened at a central portion. A seatable valve body is connected to the central portion of the diaphragm, and a spring chamber facing the other surface of the diaphragm forms a part of the valve housing and is provided in a cylindrical portion provided with an end wall on the opposite side of the diaphragm. A coil spring that is formed and energizes the diaphragm in a direction that separates the valve body from the valve seat is housed in a spring chamber, is coaxially disposed in the cylindrical portion, and is connected to the end wall. Relates to an improvement of a pressure reducing valve for a gas to which an adjusting screw for adjusting a spring load of the coil spring is screwed in accordance with an axial advance / retreat position.
[0002]
[Prior art]
Conventionally, such a pressure reducing valve for gas is already known, for example, in Japanese Patent Application Laid-Open No. 11-270718. In this case, the outer end of the adjusting screw is an outer surface of an end wall of a cylindrical part which is a part of the valve housing. A lock nut that protrudes outward from the lock screw and engages with the outer surface of the end wall via a washer, and covers a portion of the adjustment screw that protrudes outward from the lock nut. A cap is attached to the lock nut.
[0003]
[Problems to be solved by the invention]
In the above-described conventional device, an adjustment screw, a lock nut, a washer, and a cap are necessary to adjust the spring load of the coil spring, and the number of parts is relatively large.WhenIn both cases, not only the assembly man-hours are relatively increased, but also a structure in which a part protrudes from the end wall of the cylindrical part, which is a part of the valve housing, and therefore the size of the gas pressure reducing valve cannot be avoided.
[0004]
The present invention has been made in view of such circumstances, and has a structure in which the number of parts is reduced to reduce the number of assembly steps and the size can be reduced, and the spring load of the coil spring can be adjusted. An object of the present invention is to provide a gas pressure reducing valve.
[0005]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 is characterized in that the peripheral portion of the diaphragm that allows the gas pressure in the decompression chamber to act on one side is sandwiched between the valve housings, and the valve hole leading to the decompression chamber is opened in the central portion. A valve body that can be seated on the valve seat is connected to the center of the diaphragm, and a spring chamber facing the other surface of the diaphragm forms a part of the valve housing and an end wall is provided on the opposite side of the diaphragm. A coil spring formed in a cylindrical portion and energizing the diaphragm in a direction to separate the valve body from the valve seat is housed in a spring chamber, is coaxially disposed in the cylindrical portion, and is connected to the end wall. In the pressure reducing valve for gas, in which an adjusting screw that adjusts the spring load of the coil spring according to an axial advance / retreat position is screwed into the support cylinder part, the inner diameter side small-diameter hole is formed in the support cylinder part. , At least some A small-diameter in which an annular sealing member that is fitted coaxially with the small-diameter hole and elastically contacts the inner surface of the small-diameter hole is mounted on the outer surface. A shaft portion and a large-diameter shaft portion having a male screw threadedly engaged with the female screw on the outer periphery and provided with an engagement recess capable of engaging with a rotary operation tool on the outer end surface are integrally and coaxially connected. The position of the adjusting screw in the axial direction is set at a position where the outer end surface of the large-diameter shaft portion is inward of the outer surface of the end wall, and the outer end of the large-diameter shaft portion has a large diameter as a closed end. The concave portion formed at the outer end portion of the hole is filled with a solidifiable filler.
[0006]
According to the configuration of the invention described in claim 1, the spring load of the coil spring can be adjusted only by adjusting the advance / retreat position by screwing the adjusting screw into the support cylinder portion, thereby reducing the number of parts. As a result, the number of assembly steps can be reduced. In addition, the support cylinder is provided with an inner small-diameter hole and an outer large-diameter hole coaxially, and the adjusting screw is fitted into the small-diameter hole and is elastic on the inner surface of the small-diameter hole. A small-diameter shaft portion is attached to the outer surface of the annular seal member that comes into contact with the outer surface, and when the adjustment screw is inserted into the support cylinder portion, the seal member is damaged by the female screw provided on the inner surface of the large-diameter hole. Can be avoided as much as possible. The adjustment screw is screwed into the support cylinder until the outer end of the adjustment screw is inward of the outer surface of the end wall. Therefore, the adjustment screw does not protrude from the outer surface of the end wall, and the gas pressure reducing valve is downsized. Can contribute. Furthermore, the outer end of the large-diameter shaft part provided in the adjusting screw is used as a closed end, and a recess is formed in the outer end of the large-diameter hole, and the recess is filled with a filler. The adjustment screw can be prevented from rotating and erroneous operation can be prevented, and in particular, the adjustment screw can be prevented more reliably by entering the engaging recess at the outer end of the adjustment screw. Can do.
[0007]
The invention according to claim 2 is characterized in that, in addition to the configuration of the invention according to claim 1, the female screw is engraved in a large-diameter hole with a part thereof facing the recess. According to the configuration, the filler can be securely held in the recess by entering the screw groove of the female screw, and the screwed portion between the male screw of the adjusting screw and the female screw of the large-diameter hole is filled. The agent can be permeated efficiently, and the rotation of the adjusting screw can be prevented more reliably.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described based on examples of the present invention shown in the accompanying drawings.
[0009]
1 to 22 show a first embodiment of the present invention. FIG. 1 is a diagram schematically showing a configuration of a fuel gas supply device, and FIG. 2 shows a state in which the fuel gas supply device is mounted on a vehicle. 3 is a side view of the regulator, FIG. 4 is a plan view of the regulator seen from the direction of arrow 4 in FIG. 3, FIG. 5 is a bottom view of the regulator seen from the direction of arrow 5 in FIG. 4 is a sectional view taken along line 6-6 in FIG. 4, FIG. 7 is a sectional view taken along line 7-7 in FIG. 3, FIG. 8 is an enlarged longitudinal sectional view of an electromagnetic shut-off valve, FIG. 9 is an enlarged longitudinal sectional view of a primary pressure reducing valve, and FIG. FIG. 11 is a cross-sectional view taken along the line 11-11 in FIG. 10, FIG. 12 is a side view of the secondary pressure reducing valve, as viewed from the direction of arrow 12 in FIG. 13, and FIG. 14 is a sectional view taken along the line 15-15 of FIG. 14, and FIG. 16 is a sectional view taken along the line 16-16 of FIG. 17 is an enlarged view of a main part of FIG. 16, FIG. 18 is a plan view of a partition member provided in the secondary pressure reducing valve, FIG. 19 is a sectional view taken along line 19-19 in FIG. 18, and FIG. FIG. 21 is an enlarged longitudinal sectional view, FIG. 21 is a plan view of a leaf spring provided in the secondary pressure reducing valve, and FIG. 22 is a sectional view taken along line 22-22 in FIG.
[0010]
First, in FIG. 1, compressed natural gas (Compressed Natural Gas: hereinafter referred to as CNG), which is a fuel gas, is stored in one or a plurality of CNG tanks 20 at a high pressure of, for example, 25 to 1 MPa, and these CNG tanks. The container shut-off valves 21... Respectively included in the 20 ... are connected in common to the filling port 22 via the check valve 23 and commonly connected to the manual shut-off valve 24. A pressure sensor 26 and a temperature sensor 27 are attached to the pipe line 25 between 24.
[0011]
CNG from the CNG tank 20 when the container shut-off valve 21 and the manual shut-off valve 24 are opened is an oil filter for removing oil that may be mixed when the CNG tank 20 is filled with CNG by the compressor. The CNG, which is guided to the regulator RA through the high pressure line 28 having the pressure 29 and decompressed to 0.6 to 0.7 MPa by the regulator RA, is supplied to the secondary pressure reducing valve 31 which is a pressure reducing valve for gas according to the present invention. CNG guided through the low-pressure filter 30 and decompressed to, for example, 0.2 to 0.3 MPa by the secondary pressure reducing valve 31 is guided to the injector 32 of the engine E via the conduit 33, A temperature sensor 34 and a pressure sensor 35 are attached.
[0012]
In FIG. 2, in the engine room of the vehicle V, a plurality of injectors 32 included in the multi-cylinder engine E are connected in common to the fuel gas conduit 36 and are subjected to secondary decompression disposed in the vicinity of the engine E. A valve 31 is connected to a fuel gas line 36 via a line 33. Further, the low pressure filter 30 connected to the secondary pressure reducing valve 31 is also arranged in the vicinity of the engine E, and the length of the high pressure line 28 for guiding CNG from the CNG tanks 20 mounted on the rear part of the vehicle V is minimized. In order to shorten it, the regulator RA is spaced apart from the engine E and is arranged at the rear part in the engine compartment.
[0013]
The regulator RA includes a common regulator body 38A having a hot water passage 37 and a high pressure filter 39, an electromagnetic shut-off valve 40, and a primary pressure reducing valve 41. A pressure switch 42 is attached to the regulator RA. .
[0014]
The high-pressure filter 39 removes impurities contained in CNG guided from the manual shut-off valve 24 via the high-pressure line 28. The primary pressure-reducing valve 41 operates to depressurize the high-pressure CNG of 25 to 1 MPa from which impurities have been removed by the high-pressure filter 39 to, for example, 0.6 to 0.7 MPa. It is interposed between the high pressure filter 39 and the primary pressure reducing valve 41 so as to be shut off when the operation is stopped or with a signal output from the pressure switch 42. Further, the pressure switch 42 is a signal that changes the switching mode according to the CNG decompressed by the primary pressure reducing valve 41 becoming, for example, a preset set pressure, for example, 1.65 MPa or more, and shuts off the electromagnetic shut-off valve 40. Is output.
[0015]
Engine cooling water is introduced into the warm water passage 37 of the regulator body 38A from the engine E so that the temperature of the regulator body 38A does not drop too much due to the pressure reducing action of the primary pressure reducing valve 41. The thermostat 43 arranged separately from the regulator body 38A is closed when the engine coolant flowing through the hot water passage 37 exceeds, for example, 70 ° C. so that the temperature of the regulator body 38A does not rise too much. To do.
[0016]
3 to 7 together, the regulator body 38A is formed to have a substantially square cross-sectional shape, and is formed to slightly bulge outward from the outer surface of the regulator body 38A. The high pressure filter 39 is attached to the regulator body 38A from the first side surface 44 side, and the electromagnetic shut-off valve 40 is attached to the regulator body 38A on the second side surface 45 side opposite to the first side surface 44. Further, a third side surface 46 connecting the first and second side surfaces 44 and 45 of the outer surface of the regulator body 38A is provided with a recess serving as the hot water passage 37, and the third side surface is closed so as to close the recess. A pair of connecting pipes 48 and 49 for supplying and discharging engine cooling water to and from the hot water passage 37 are attached to the lid plate 47 fastened to 46.
[0017]
The regulator body 38A has a first end face 50 orthogonal to the first to third side faces 44 to 46, and a second end face 51 opposite to the first end face 50, and the regulator end on the first end face 50 side. A primary pressure reducing valve 41 is mounted on the body 38A, and a pressure switch 42 is mounted on a protrusion 51a provided on the regulator body 38A so as to protrude from the second end surface 51.
[0018]
Hereinafter, the configurations of the high-pressure filter 39, the electromagnetic shut-off valve 40, and the primary pressure reducing valve 41 constituting the regulator RA will be sequentially described.
[0019]
[High-pressure filter 39]; With particular attention to FIG. 7, the first side surface 44 of the regulator body 38A is provided with a recess 53, and a pipe joint 54 is connected to the inner end of the outer end opening of the recess 53. A high-pressure line 28 that leads CNG from the manual shut-off valve 24 is connected to the outer end portion of the pipe joint 54 by screwing the annular seal member 55 between the regulator body 38A and the regulator body 38A. A high pressure filter 39 is fitted in the recess 53 so as to be spaced from the inner end of the pipe joint 54, and the high pressure filter 39 is interposed between the high pressure filter 39 and the pipe joint 54. A spring 56 is provided that exerts a resilient force that presses against the inner end blocking portion of the recess 53.
[0020]
An annular unpurified chamber 57 communicating with the inside of the pipe joint 54 is formed between the outer periphery of the high pressure filter 39 fitted in the recess 53 and the regulator body 38A. A passage 59 leading to the purification chamber 58 is provided. Thus, the CNG guided through the high-pressure line 28 passes through the high-pressure filter 39 from the unpurified chamber 57 and flows into the purification chamber 58, and the CNG from which impurities have been removed is guided to the passage 59. .
[0021]
[Electromagnetic cutoff valve]; Referring also to FIG. 8, the electromagnetic cutoff valve 40 is mounted at a position corresponding to the high-pressure filter 39 on the second side face 45 of the regulator body 38A.
[0022]
The electromagnetic shut-off valve 40 includes a coil assembly 60, a guide cylinder 61 made of a non-magnetic material having one end inserted into the coil assembly 60 and the other end fixed to the regulator body 38A, and the guide cylinder 61 A fixed core 62 fixed to the guide cylinder 61 so as to close one end, a plunger 63 slidably fitted into the guide cylinder 61 facing the fixed core 62, and between the fixed core 62 and the plunger 63 A return spring 64 provided, a magnetic metal solenoid housing 65 fastened to the fixed core 62 so as to cover the coil assembly 60, and the coil assembly 60 sandwiched between the solenoid housing 65 and the regulator body 38 </ b> A. A magnetic support frame 66 to be screwed and a valve member 67 held by the plunger 63 on the side opposite to the fixed core 62 are provided.
[0023]
The coil assembly 60 is formed by covering a bobbin 68 made of synthetic resin and a coil 69 wound around the bobbin 68 with a covering portion 70 made of synthetic resin, and the regulator body 38 </ b> A side of the covering portion 70. In this portion, a coupler part 70a facing a pair of connection terminals 71 connected to the coil 69 is integrally provided so as to protrude outward, and a conductor (not shown) is connected to the coupler part 70a. The
[0024]
The second side surface 45 of the regulator body 38A has a small-diameter hole 73 whose inner end is closed, and a large-diameter hole 74 which is larger in diameter than the small-diameter hole 73 and is coaxially connected to the outer end of the small-diameter hole 73. An annular stepped portion 75 is provided between each other. On the outer surface of the other end side of the guide tube 61 that is inserted into the bobbin 59 at one end side, a flange portion 61a that makes the outer peripheral surface approach and face the inner surface of the large diameter hole 74 is integrally provided so as to project outward in the radial direction. The other end portion of the guide tube 61 is inserted into the large-diameter hole 74 so that the annular seal member 76 is sandwiched between the flange portion 61 a and the step portion 75.
[0025]
The magnetic support frame 66 is assembled to the regulator body 38 </ b> A by being screwed into the large diameter hole 74. Moreover, the guide member 61 is also fixed to the regulator body 38A by sandwiching the seal member 76 and the flange 61a between the stepped portion 75 and the magnetic support frame 66.
[0026]
A screw shaft portion 62 a penetrating through the central portion of the closed end of the solenoid housing 65 formed in a bottomed cylindrical shape is integrally connected to the fixed core 62, and the protruding portion from the solenoid housing 65 of the screw shaft portion 62 a A cap nut 78 is screwed with a washer 77 interposed between the solenoid housing 65 and the central portion of the closed end of the solenoid housing 65 is fastened to the fixed core 62 by tightening the cap nut 78. Become.
[0027]
The other end side of the guide cylinder 61 is fixed to the regulator body 38A while being inserted into the large diameter hole 74, and the plunger 63 is slidably fitted to the guide cylinder 61, whereby the small diameter hole 73 provided in the regulator body 38A. A main valve chamber 79 is formed between the inner end of the guide cylinder 61 and the other ends of the guide cylinder 61 and the plunger 63. In addition, a passage 59 leading to the purification chamber 58 of the high-pressure filter 39 communicates with the main valve chamber 79, and CNG from which impurities have been removed by the high-pressure filter 39 is introduced into the main valve chamber 79.
[0028]
A passage 80 is provided in the regulator body 38A so as to open at the center of the inner end portion of the small diameter hole 73, and the main valve chamber 79 is formed so as to surround the opening end of the passage 80 to the main valve chamber 79. An annular valve seat 81 protruding slightly to the side is provided on the regulator body 38A.
[0029]
The valve member 67 has a tapered surface with a small diameter toward the plunger 63 side at one end surface and is formed in a disk shape so as to face the pilot valve portion 67a on one end side and the inner end portion of the small diameter hole 73. The main valve portion 67b on the other end side formed in the shape of the pilot valve portion is integrally connected via a connecting cylinder portion 67c forming a step between the valve portions 67a and 67b. The diameter of 67a is set smaller than the diameter of the main valve portion 67b. A central portion of the valve member 67 is provided with a first passage 82 that always communicates with the passage 80 and a second passage 83 that communicates with the first passage 82 and opens at the center of one end surface of the pilot valve portion 67a. The second passage 83 is formed with a smaller diameter than the first passage 82.
[0030]
A concave portion 84 into which the pilot valve portion 67 a is inserted is provided at the end facing the main valve chamber 79 in the plunger 63, and the pilot valve portion 67 a is a C-shaped retaining ring 85 fixed to the other end of the plunger 63. Thus, a pilot valve chamber 86 is formed between the pilot valve portion 67 a and the plunger 63 so as to be prevented from being detached from the recess 84, and communicates with the main valve chamber 79. In addition, a rubber seal 87 is embedded in the central portion of the closed end of the recess 84 to block the opening of the second passage 83 to the pilot valve chamber 86 when the central portion of the one end surface of the pilot valve portion 67a is seated. Thus, the retaining ring 85 is fixed to the plunger 63 at a position where the pilot valve portion 67 a can move relative to the plunger 63 between the closed end of the recess 84 and the retaining ring 85.
[0031]
An annular rubber seal 88 is embedded in the surface of the main valve portion 67b facing the closed end of the small diameter hole 73 so as to be seated on the valve seat 81 and shut off between the main valve chamber 79 and the passage 80.
[0032]
In such an electromagnetic shut-off valve 40, when the power supply to the coil 60 is cut off, the plunger 63 moves away from the fixed core 62 by the spring force of the return spring 64, and the rubber seal 88 of the main valve portion 67 b moves to the valve seat 81. The pilot valve portion 67a is seated on the rubber seal 87 and also between the pilot valve chamber 86 and the passage 80, and the high pressure CNG is connected to the passage 80 side. Supply is stopped.
[0033]
On the other hand, when electric power is supplied to the coil 60, the plunger 63 first moves to the fixed core 62 side so as to separate the pilot valve portion 67 a from the rubber seal 87, and communicates with the passage 80 through the first passage 82. The two passages 83 communicate with the pilot valve chamber 86. As a result, CNG gradually flows from the main valve chamber 79 to the passage 80 through the pilot valve chamber 86, the second passage 83, and the first passage 82, whereby the main valve chamber 79 and the passage 80 enter the main valve portion 67b. The difference in pressure acting from the side is reduced. Thus, when the electromagnetic force by the coil 60 overcomes the differential pressure acting on the main valve portion 67b, the plunger 63 further moves to the fixed core 62 side, and the rubber seal 88 of the main valve portion 67b moves to the valve seat 81. The CNG flows away from the main valve chamber 79 to the passage 80.
[0034]
[Primary pressure reducing valve 41]; Referring also to FIG. 9, a plurality of valve housings 90 of the primary pressure reducing valve 41 are provided on the first end face 50 side portion of the regulator body 38A and the first end face 50 of the regulator body 38A. The cover 91 is fastened by the bolts 92..., And the peripheral edge of the diaphragm 93 is sandwiched between the first end face 50 of the regulator body 38A and the cover 91 having the cylindrical portion 91a.
[0035]
The first end surface 50 is provided with a recess 95 that forms a decompression chamber 94 between the first end surface 50 and the diaphragm 93. The regulator body 38A has one end opened at the center of the decompression chamber 94, and the second end surface 51 side. A mounting hole 97 is provided to extend to. The attachment hole 97 includes a first hole 97a having one end opened at the central portion of the closed end of the recess 95, a first hole 97a having a smaller diameter than the first hole 97a, and one end coaxially connected to the other end of the first hole 97a. A second hole 97b, a third hole 97c having a smaller diameter than the second hole 97b, one end coaxially connected to the other end of the second hole 97b, and a third hole having a smaller diameter than the third hole 97c. The other end of the portion 97c is constituted by a fourth hole portion 97d having one end connected coaxially, and a passage 80 for guiding CNG from the electromagnetic shut-off valve 40 is opened on the inner surface of the second hole portion 97b.
[0036]
A cylindrical valve seat member 98 is screwed into the first hole portion 97a of the mounting hole 97 so as to sandwich an annular seal member 99 between the step portion between the first and second hole portions 97a and 97b. Is done. That is, a female screw 100 is formed on the inner surface of one end of the first hole 97 a in the mounting hole 97, and the valve seat member 98 is screwed into the female screw 100.
[0037]
On the end face of the valve seat member 98 on the decompression chamber 94 side, a plurality of, for example, four, for example, four grooves 101 extending in the radial direction of the valve seat member 98 in a plane perpendicular to the axis of the mounting hole 97 are formed. Two protrusions 102 are provided so that the grooves 101 are arranged in a cross shape. Thus, when the valve seat member 98 is screwed into the female screw 100, the valve seat member 98 can be rotated by engaging a tool (not shown) with the grooves 101 arranged in a cross shape. The member 98 can be easily attached to the regulator body 38A.
[0038]
A valve chamber 103 communicating with the passage 80 is formed between the valve seat member 98 and the step portion between the second and third hole portions 97 b and 97 c in the mounting hole 97. Further, the valve seat member 98 is integrally provided with an inward flange 98a projecting radially inward at the end on the decompression chamber 94 side, and a valve communicating with the decompression chamber 94 on the inner periphery of the inward flange 98a. A hole 104 is formed, and a tapered valve seat 105 that faces the valve chamber 103 is formed on the inner surface of the inward flange 98a with the valve hole 104 opened in the center.
[0039]
A valve body 106 made of synthetic resin that can be seated on the valve seat 105 is accommodated in the valve chamber 103, and the valve body 106 is fixed to a valve shaft 107 that is arranged coaxially with the valve hole 104.
[0040]
The valve body 106 is formed in a cylindrical shape with one end surface facing the valve seat 105 tapered to be seated on the valve seat 105 having a tapered shape, and the valve shaft 107 is elastically formed on the valve body 106. By being fitted to each other, the valve shaft 107 is fixed. In addition, an O-ring 108 that elastically contacts the inner surface of the valve body 106 is attached to the outer surface of the valve shaft 107.
[0041]
One end portion of the valve shaft 107 is supported by the regulator body 38A so as to be movable in the axial direction by an O-ring 109 interposed between the mounting hole 97 and the inner surface of the third hole portion 97c. Further, the outer surface of the valve body 106 is in sliding contact with the inner surface of the valve seat member 98 at a plurality of positions spaced at equal intervals in the circumferential direction, and between the valve body 106 and the valve seat member 98 between these sliding contact portions. Is formed with a flow passage 110 extending along the axial direction of the valve shaft 107.
[0042]
A holding plate 111 for holding the O-ring 109 between the third and fourth hole portions 97c and 97d in the mounting hole 97 has a step portion between the second and third hole portions 97b and 97c. A spring 112 is provided between the holding plate 111 and the valve body 106 to exert a spring force in a direction in which the valve body 106 is seated on the valve seat 105.
[0043]
A spring chamber 115 is formed between the cover 91 and the diaphragm 93, and a coil spring 116 that biases the diaphragm 93 toward the decompression chamber 94 is housed in the spring chamber 115.
[0044]
A housing hole 117 extending coaxially with the valve hole 104 is provided in the cylindrical portion 91a of the cover 91 so as to open the outer end, and the housing hole 117 is a screw hole portion 117a on the axially outer side. And an axially inward sliding hole 117b having a larger diameter than the screw hole 117a and coaxially connected to the screw hole 117a.
[0045]
A first diaphragm retainer 118 integrally having a cylindrical portion 118a penetrating through the central portion of the diaphragm 93 and projecting toward the spring chamber 115 is brought into contact with a surface facing the decompression chamber 94 side of the central portion of the diaphragm 93. The central portion of the diaphragm 93 is engaged with the annular step portion 119 provided on the outer surface of the cylindrical portion 118 a so that the central portion of the diaphragm 93 is sandwiched between the first diaphragm 118 and the surface facing the spring chamber 115. The 2nd diaphragm retainer 120 is contact | abutted.
[0046]
A diaphragm rod 121 is attached to the other end of the valve shaft 107, that is, the end on the diaphragm 93 side.ButThe diaphragm rod 121 is fastened coaxially, and is inserted into the central portion of the first diaphragm retainer 118 from the decompression chamber 94 side. An annular step 122 facing the decompression chamber 94 is provided on the inner surface of the cylindrical portion 118 a of the first diaphragm retainer 118, and the diaphragm rod 121 is engaged with the annular step 122. Further, the second diaphragm retainer 120 is sandwiched between the diaphragm 93 and the auxiliary retainer 123, and a screw shaft portion 121a provided on the diaphragm rod 121 at a protruding portion from the cylindrical portion 118a is provided between the auxiliary retainer 123 and the screw shaft portion 121a. A nut 125 interposing a washer 124 is screwed. By tightening the nut 125, the central portion of the diaphragm 93 is sandwiched between the diaphragm retainers 118 and 120, and the valve shaft 107 is fixed to the central portion of the diaphragm 93. Will be. Moreover, in order to seal between the decompression chamber 94 and the spring chamber 115, an O-ring 126 mounted on the outer periphery of the diaphragm rod 121 elastically contacts the inner surface of the cylindrical portion 118a.
[0047]
By the way, the diaphragm 93 has a relatively large thickness at the connecting portion of the valve shaft 107, that is, at the central portion, and a portion sandwiched between the regulator body 38A and the cover 91, that is, at the peripheral portion. The portion connecting the peripheral portions is formed in a relatively thin curved surface shape. According to such a diaphragm 93, the pressure resistance of the diaphragm 93 can be improved, and at a low temperature. Responsiveness can also be improved.
[0048]
The second diaphragm retainer 120 is integrally provided on the outer peripheral side with a deflection regulating portion 120a that regulates the deflection of the diaphragm 93 toward the spring chamber 115. The bending restricting portion 120 a is formed in a curved shape that swells toward the spring chamber 115, and the outer peripheral edge of the bending restricting portion 120 a is close to and faces the inner surface of the cover 91. In addition, the thickness of the diaphragm 93 is formed larger than the gap at a portion corresponding to the gap between the outer edge of the bending restricting portion 120a and the inner peripheral surface of the cover 91.
[0049]
Due to such a shape of the second diaphragm retainer 120, it is possible to smoothly bend the diaphragm 93 from the second diaphragm retainer 120 to the inner surface of the cover 91 even when a pressure higher than a specified pressure is applied to the decompression chamber 94. Further, it is possible to prevent the diaphragm 93 from being bent toward the spring chamber 115 at the outer edge of the second diaphragm retainer 120, to prevent the life of the diaphragm 93 from being shortened by the bending, and to improve the durability of the diaphragm 93..
An adjustment screw 127 is threadably engaged with the outer end opening of the storage hole 117, that is, the screw hole 117a, and the protrusion of the adjustment screw 127 from the cover 91 is adjusted to adjust the advance / retreat position of the adjustment screw 127. The lock nut 128 is screwed. The adjustment screw 127 is provided with an opening hole 129 for opening the spring chamber 115 to the atmosphere.
[0050]
The coil spring 116 is contracted between the adjustment screw 126 and a leaf spring 132 that is in contact with the auxiliary retainer 123 attached to the diaphragm 93 on the spring chamber 115 side. Therefore, the spring load of the coil spring 116 can be adjusted by adjusting the advance / retreat position of the adjustment screw 126.
[0051]
Referring to FIGS. 10 and 11 together, the leaf spring 132 is for imparting sliding resistance to the diaphragm 93 by frictional contact with the inner surface of the cylindrical portion 91a which is a part of the valve housing 90. The closed retainer 123 attached to the central portion of the diaphragm 93 on the spring chamber 115 side and the closed end between the coil spring 116 and a cylindrical cup portion 132a having a bottom, and the inner surface of the sliding hole 117b in the cylindrical portion 91a Are formed at a plurality of leaf portions 132b, 132b,... Which are integrally connected to the open end of the cup portion 132a so as to be slidably contacted at a plurality of locations, for example, eight locations, equally spaced in the circumferential direction.
[0052]
In the regulator body 38A, a plurality of, for example, two outlet passages 133 and 133 passing through one end of the decompression chamber 94 are formed in parallel with the mounting hole 97, and the other ends of these outlet passages 133 and 133 are opened in common. A connection hole 134 is provided in the protrusion 51a disposed on the second end face 51 side of the regulator body 38A.
[0053]
In such a primary pressure-reducing valve 41, when high-pressure CNG does not flow into the valve chamber 103, the diaphragm 93 is bent toward the pressure-reducing chamber 94 by the spring force of the coil spring 116, and the valve body 106 is the valve seat 105. The valve hole 104 is opened away from the valve. Thus, the high-pressure CNG that has flowed into the valve chamber 103 flows into the decompression chamber 94 from the valve hole 104, and the pressure in the decompression chamber 94 moves the diaphragm 93 toward the spring chamber 115 against the spring force of the coil spring 116. When the valve body 106 is increased to be bent, the valve body 106 is seated on the valve seat 105 and the valve hole 104 is closed. By repeating such opening and closing of the valve hole 104, CNG that flows in at a high pressure of 25 to 1 MPa is decompressed to, for example, 0.6 to 0.7 MPa and flows from the decompression chamber 94 to the outlet passages 133 and 133.
[0054]
With particular attention to FIG. 6, the protrusion 51a of the regulator body 38A is provided with a bottomed mounting hole 135 for screwing and mounting the pressure switch 42, and the mounting hole 135 has an inner surface on the closed end side. An opening detection hole 136 is provided in the regulator body 38 </ b> A so as to be coaxial with the attachment hole 97. The regulator body 38A is provided with a communication hole 137 connecting the connection hole 134 and the detection hole 136. The pressure switch 42 is depressurized by the primary pressure reducing valve 41 and flows from the outlet passages 133, 133 to the connection hole 134. The switching mode is changed according to the pressure of CNG being, for example, 1.65 MPa or more.
[0055]
The secondary pressure reducing valve 31 is connected to the connection hole 134 of the regulator RA, and the configuration of the secondary pressure reducing valve 31 will be described next.
[0056]
[Secondary pressure reducing valve 31]; Referring also to FIGS. 12 to 16, the valve housing 140 of the secondary pressure reducing valve 31 includes a body 141, a partition member 142, and a cover 143, and the body 141 and the cover 143. .. Are fastened by a plurality of bolts 144, 144... With a partition wall member 142 interposed therebetween, and both ends of a plurality of knock pins 145... Inserted through the partition wall member 142 are respectively fitted to the body 141 and the cover 143. As a result, the relative positions of the body 141, the partition member 142, and the cover 143 are fixed.
[0057]
The periphery of the partition member 142 is sandwiched between the body 141 and the cover 143, and the periphery of the diaphragm 146 is sandwiched between the partition member 142 and the cover 143. Thus, a decompression chamber 147 is formed between the body 141 and the partition member 142, and a pressure action chamber 148 leading to the decompression chamber 147 is formed between one surface of the partition member 142 and the diaphragm 146, and the other surface of the diaphragm 146 and A spring chamber 149 is formed between the covers 143.
[0058]
Referring also to FIG. 17, the body 141 is provided with a recess 150 that opens toward the partition member 142 so as to form the decompression chamber 147 with the partition member 142, and the recess 150. A bottomed mounting hole 151 is provided with one end opened at the central portion of the closed end and the other end closed. In addition, a protruding portion 152 that protrudes toward the decompression chamber 147 is provided at the other end blocking portion of the mounting hole 151.
[0059]
A female screw 153 is engraved on the inner surface of the mounting hole 151 on the side of the decompression chamber 147, and a cylindrical valve seat member 154 is screwed into the female screw 153. An O-ring 155 that elastically contacts is attached.
[0060]
In addition, a plurality of, for example, four grooves 156 extending in the radial direction of the valve seat member 154 in a plane perpendicular to the axis of the mounting hole 151 are formed on the end face of the valve seat member 154 on the decompression chamber 147 side. Four protrusions 157... Are projected, and the grooves 156... Are arranged in a cross shape. Thus, when the valve seat member 154 is screwed into the female screw 153, the valve seat member 154 can be rotated by engaging a tool (not shown) with the cross-shaped grooves 156. The member 154 can be easily attached to the body 141.
[0061]
A valve chamber 158 is formed between the valve seat member 154 and the other end blocking portion of the mounting hole 151, and the valve chamber 158 has an input provided in the body 141 so as to open to the side surface of the body 141. Port 159 is communicated. Thus, CNG from the primary pressure reducing valve 41 is introduced into the input port 159, that is, the valve chamber 158.
[0062]
Further, the body 141 is provided with an output port 160 that opens to a side surface different from the side surface on which the input port 159 is provided, and a passage 161 that communicates the output port 160 with the decompression chamber 147. CNG is guided to the fuel gas pipe line 36 through the passage 161 and the output port 160.
[0063]
The valve seat member 154 is integrally provided with an inward flange 154a projecting radially inward at the end on the decompression chamber 147 side, and a valve hole communicating with the decompression chamber 147 on the inner periphery of the inward flange 154a. 162 is formed, and an annular valve seat 163 facing the valve chamber 158 is formed on the inner peripheral portion of the inward flange 154a so that the valve hole 162 is opened at the central portion and protrudes toward the valve chamber 158. The
[0064]
The raised portion 152 is provided with a bottomed sliding hole 164 that is open to the valve hole 162 side and coaxial with the valve hole 162, and the valve body 165 is slidably fitted into the sliding hole 164. . Moreover, an annular rubber seal 166 that can be seated on the valve seat 163 is fixed to the valve body 165.
[0065]
The valve body 165 is provided with a through hole 167 having an internal thread 167a at least at a portion on the decompression chamber 147 side across both ends in the axial direction, and one end of the valve shaft 168 coaxial with the valve hole 162 is screwed into the internal thread 167a. Combined. That is, the valve body 165 is fixed to one end of the valve shaft 168.
[0066]
A back pressure chamber 169 is formed between the valve body 165 and the closed end of the sliding hole 164, and an O-ring 170 that elastically slidably contacts the inner surface of the sliding hole 164 on the outer surface of the valve body 165. Is installed.
[0067]
Referring to FIGS. 18 and 19 together, the partition wall member 142 is formed in a dish shape having a circular recess 171 facing the diaphragm 146 side so as to form a pressure action chamber 148 between the diaphragm member 146 and the diaphragm 146. An annular groove 172 into which a ring-shaped outer peripheral seal portion 146 a provided on the peripheral edge of the diaphragm 146 is fitted is provided in the partition wall member 142 so as to surround the recess 171.
[0068]
Further, the partition member 142 is provided with a through hole 173 that allows the valve shaft 168 to pass through the center of the partition member 142 so as to be movable in the axial direction, and the stroke of the diaphragm 146 toward the side of reducing the volume of the pressure working chamber 148. A plurality of, for example, four restricting protrusions 174, 174... For restricting the limit are arranged so as to surround the through-hole 173 and project from the diaphragm 146 side.
[0069]
The partition member 142 is provided with a communication hole 175 for allowing the pressure action chamber 148 to communicate with the decompression chamber 147.
[0070]
In FIG. 20, the diaphragm 146 is fitted in the annular groove 172 of the partition member 142 so that the ring-shaped outer peripheral seal portion 146 a sandwiched between the partition member 142 and the cover 143 is connected to the valve shaft 168 in the center. A cylindrical valve shaft coupling portion 146b that is disposed and a flexure portion 146c that has a cross-sectional shape that swells toward the spring chamber 149 and is disposed on the inner side of the outer peripheral seal portion 146a are integrally provided. In a natural state in which an external force does not act on the diaphragm 146, the diaphragm 146 is formed so that the inner peripheral portion of the bending portion 146c is offset from the outer peripheral portion by a set offset amount e toward the decompression chamber 147 side. The
[0071]
A first diaphragm retainer 176 is brought into contact with the surface of the diaphragm 146 facing the pressure acting chamber 148 between the bent portion 146c and the valve shaft connecting portion 146b, and the spring chamber of the diaphragm 146 is located inward of the bent portion 146c. On the surface facing the 149 side, a second diaphragm retainer 178 having an insertion hole 177 at the center is a first diaphragm.RetainerThe diaphragm 146 is brought into contact with the gap 176.
[0072]
The valve shaft 168 with the valve body 165 fixed to one end includes a valve hole 162 of the valve seat member 154, a through hole 173 of the partition wall member 142, a valve shaft connecting portion 146b of the diaphragm 146, and first and second diaphragm retainers 176, A central portion of 178 extends coaxially through the spring chamber 149 side, and an annular step 179 and a valve shaft coupling portion 146 b that engage with the inner peripheral edge of the first diaphragm retainer 176 are connected to the second diaphragm retainer 178. An annular step 180 sandwiched therebetween is provided on the valve shaft 168, and an O-ring 199 that elastically contacts the inner surface of the through hole 137 is mounted on the outer periphery of the valve shaft 168.
[0073]
A screw shaft portion 168a is provided at the other end portion of the valve shaft 168 that passes through the valve shaft coupling portion 146b of the diaphragm 146 and the insertion hole 177 of the second diaphragm retainer 178 and protrudes into the spring chamber 149, and the second diaphragm retainer 178. A nut 182 is screwed onto the screw shaft portion 168a with a washer 181 interposed therebetween. By tightening the nut 182, the center portion of the diaphragm 146 is sandwiched between the first and second diaphragm retainers 176 and 178, and the valve shaft 168 is connected to the center portion of the diaphragm 146. In addition, the valve shaft 168 is provided with a communication passage 183 that allows the decompression chamber 149 to communicate with the back pressure chamber 169 through the through hole 167 of the valve body 165.
[0074]
Thus, a diaphragm 146 having a central portion sandwiched between the two diaphragm retainers 176 and 178, a valve shaft 168 connected to the central portion of the diaphragm 146, and a valve body 165 fixed to the valve shaft 168 include a valve housing. When the diaphragm 146 is in a natural state avoiding the action of an external force when assembled to 140, the rubber seal 166 of the valve body 165 is assembled so as to be in a position away from the valve seat 163.
[0075]
The cover 143 has a cylindrical portion 143a provided with an end wall 143b at the end opposite to the diaphragm 146, and is disposed coaxially within the cylindrical portion 143a at the center of the end wall 143b. The opened support cylinder part 184 is continuously provided integrally.
[0076]
A small diameter hole 185 on the inner side in the axial direction and a large diameter hole 186 on the outer side in the axial direction in which the female screw 187 is at least partially engraved are provided in the support cylinder portion 184 in a coaxial manner. An adjustment screw 188 is screwed onto 184 so that the advance / retreat position can be adjusted. The adjustment screw 188 is fitted into the small diameter hole 185 and has a small diameter shaft portion 188a on which an annular seal member 189 that elastically contacts the inner surface of the small diameter hole 185 is mounted on the outer surface, and a male screw that is screwed into the female screw 187. A large-diameter shaft portion 188b having an engagement recess 191 capable of engaging with a rotary operation tool is integrally and coaxially connected to the outer end surface of the adjustment screw 188. The axial position is set so that the inner end of the small diameter shaft portion 188a protrudes into the spring chamber 149 and the outer end of the large diameter shaft portion 188b is positioned inward from the outer surface of the end wall 143b.
[0077]
By such setting of the axial position of the adjusting screw 188, a recess 192 having the outer end of the large-diameter shaft portion 188b as a closed end is formed in the outer end portion of the large-diameter hole 186, and the recess 192 is solidified. The resulting filler 193 is filled. In addition, a seal 194 is attached to the outer surface of the end wall 143b so as to cover the recess 192.
[0078]
The female screw 187 to which the adjusting screw 188 is screwed is engraved in the large-diameter hole 186 so that a part thereof faces the concave portion 192.
[0079]
In the spring chamber 149, a retainer 195 is in contact with and supported by the inner end of the adjusting screw 188. The retainer 195 and the second diaphragm retainer 178 mounted on the center of the diaphragm 146 on the spring chamber 149 side are in contact with each other. A coil spring 196 that biases the diaphragm 146 in a direction in which the valve body 165 separates from the valve seat 163 is contracted between the leaf spring 197 and the leaf spring 197 that is in contact therewith. Therefore, the spring load of the coil spring 196 can be adjusted by adjusting the advance / retreat position of the adjustment screw 180.
[0080]
Referring to FIG. 21 and FIG. 22 together, the leaf spring 197 is for imparting sliding resistance to the diaphragm 146 by frictional contact with the inner surface of the cylindrical portion 143a that is a part of the valve housing 140. A cylindrical cup portion 197a having a closed end sandwiched between a second diaphragm retainer 178 and a coil spring 196 mounted on the center portion of the diaphragm 146 on the spring chamber 149 side, and a circumferential direction of the inner surface of the cylindrical portion 143a And a plurality of leaf portions 197b, 197b, which are integrally connected to the opening end of the cup portion 197a so as to be slidably contacted at a plurality of locations, for example, five locations at equal intervals.
[0081]
Further, a connecting pipe 198 is connected to the cover 143, and intake negative pressure of the engine E is introduced into the spring chamber 149 through the connecting pipe 198 and a pipe line (not shown) connected to the connecting pipe. Is done.
[0082]
In such a secondary pressure reducing valve 31, when CNG does not flow into the valve chamber 158, the diaphragm 146 is bent toward the pressure reducing chamber 147 by the spring force of the coil spring 196, and the valve body 165 is moved from the valve seat 163. The valve hole 162 is opened away. Thus, CNG that has flowed into the valve chamber 158 flows into the pressure action chamber 148 from the valve hole 162 through the pressure reducing chamber 147, and the differential pressure between the pressure action chamber 158 and the spring chamber 149 resists the spring force of the coil spring 196. When the diaphragm 146 is increased to the extent that the diaphragm 146 is bent toward the spring chamber 149 side, the rubber seal 166 of the valve body 165 is seated on the valve seat 163 and the valve hole 162 is closed, and the valve hole 162 is opened. -By repeating the closing, CNG that has flowed into the valve chamber 158 at, for example, 0.6 to 0.7 MPa is decompressed to, for example, 0.2 to 0.3 MPa, and the output port 160 and the pipe line 33 are connected from the decompression chamber 147. To the injectors 32 of the engine E.
[0083]
Next, the operation of the first embodiment will be described. The high pressure filter 39, the electromagnetic shutoff valve 40, the primary pressure reducing valve 41, the pressure switch 42 and the secondary pressure interposed between the CNG tank 20 and the injector 32 of the engine E are described. Among the pressure reducing valves 31, a high pressure filter 39, an electromagnetic cutoff valve 40, and a primary pressure reducing valve 41 are a passage 59 connecting the high pressure filter 39 and the electromagnetic cutoff valve 40, a passage 80 connecting the electromagnetic cutoff valve 40 and the primary pressure reducing valve 41, A regulator RA is configured by being disposed in a common regulator body 38A having an outlet passage 133... Having one end connected to the primary pressure reducing valve 41, and a pressure switch 42 is attached to the regulator RA.
[0084]
Thus, by integrating the high pressure filter 39, the electromagnetic shut-off valve 40 and the primary pressure reducing valve 41 on the high pressure side into the regulator body 38A to constitute the regulator RA, the high pressure portion and the low pressure portion are all integrated to constitute the regulator. Compared to the one, the passage structure of the regulator body 38A is simplified, and the processing applied to the regulator body 38A is facilitated accordingly. In addition, the regulator RA can be made compact, and the restrictions on the layout with other components generated when the regulator RA is mounted on the vehicle V can be reduced.
[0085]
Further, since the valve housing 140 of the secondary pressure reducing valve 31 on the low pressure side is formed separately from the regulator body 38A, the valve housing 140 of the secondary pressure reducing valve 31 is made of a material having a relatively low strength. Cost reduction can be achieved.
[0086]
Further, the primary pressure reducing valve 41 includes a leaf spring 132 that imparts sliding resistance to the diaphragm 93 by frictional contact with a sliding hole portion 117b in the cylindrical portion 91a that is a part of the valve housing 90. The pressure reducing valve 31 includes a leaf spring 197 that imparts sliding resistance to the diaphragm 146 by frictional contact with the inner surface of the cylindrical portion 143 a that is a part of the valve housing 140.
[0087]
These leaf springs 132 and 197 are cylindrical cups having a bottom with a closed end sandwiched between retainers 123 and 178 and coil springs 116 and 196 attached to the central portions of the diaphragms 93 and 146 on the spring chambers 115 and 149 side. The portions 132a and 197a are integrally connected to the opening ends of the cup portions 132a and 197a so as to be slidably contacted at a plurality of positions at equal intervals in the circumferential direction of the inner surfaces of the cylindrical portions 91a and 143a. The plurality of leaf portions 132b, 132b... 197b, 197b.
[0088]
That is, the leaf springs 132 and 197 are caused to self-excitedly vibrate by the coil springs 116 and 196 by elastically sliding the plurality of leaf portions 132b, 132b... 197b, 197b to the inner surfaces of the cylindrical portions 91a and 143a. Since the opposing sliding resistance is applied to the diaphragms 93 and 146, even if the diameter of the cylindrical portions 91a and 143a decreases as the diameter of the diaphragms 93 and 146 decreases, the leaf springs 132 and 197 The contact area with the cylindrical portions 91a and 143a does not change, and therefore the sliding resistance exerted by the leaf springs 132 and 197 does not increase with the downsizing of the primary pressure reducing valve 41 and the secondary pressure reducing valve 31. Further, even if the temperature changes, the sliding resistance due to the elastic sliding contact with the cylindrical portions 91a and 143a of the leaf springs 132 and 197 changes. Therefore, the diaphragm 93, 146 can be provided with a stable sliding resistance against the self-excited vibration of the coil springs 116, 196 regardless of the size reduction and temperature change of the diaphragms 93, 146, and the primary pressure reduction. It is possible to prevent the responsiveness of the valve 41 and the secondary pressure reducing valve 31 from being lowered.
[0089]
Moreover, since the plurality of leaf portions 132b, 132b... 197b, 197b... Are supported by the cup portions 132a, 197a having relatively high rigidity, the assembly of the leaf springs 132, 197 into the valve housings 90, 140 is performed. At the time of attachment, the leaf portions 132b, 132b,... 197b, 197b,.
[0090]
In the secondary pressure reducing valve 31, the peripheral portion of the diaphragm 146 is sandwiched between the partition member 142 and the cover 143 sandwiched between the cover 143 and the body 141, and the decompression chamber 147 is disposed between the partition member 142 and the body 141. The pressure action chamber 148 communicating with the decompression chamber 147 is formed between the one surface of the diaphragm 146 and the partition wall member 142. For this reason, the structure of the portion of the body 141 facing the decompression chamber 147 can be simplified, the processing accuracy of the body 141 can be improved, and the partition wall member 142 can be easily processed while being separated from the body 141. it can.
[0091]
The diameter of the pressure working chamber 148 also changes in accordance with the change in the diameter of the diaphragm 146, but the diameter of the decompression chamber 147 with the partition member 142 interposed between the pressure working chamber 148 depends on the change in the diameter of the diaphragm 146. However, it is not necessary to set the diameter of the decompression chamber 147 to be small even if the diameter of the diaphragm 146 is set to be small based on the demand for downsizing of the secondary pressure reducing valve 31. It is possible to avoid a change in flow rate characteristic in which the gas pressure in the chamber 147 is greatly reduced from the target control pressure.
[0092]
Moreover, since the gas pressure in the decompression chamber 147 does not directly act on one surface of the diaphragm 146, the diaphragm 146 can be avoided by avoiding an excessive load acting on the diaphragm 146 when the gas pressure in the decompression chamber 147 changes greatly. Can be protected.
[0093]
Further, since the body 141 is provided with a sliding hole 164 for fitting the valve body 165 in a slidable manner, the axial movement of the valve body 165 and the valve shaft 168 is caused by the inner surface of the sliding hole 164 of the body 141, It will be supported at two locations with the inner surface of the through-hole 173 provided in the partition wall member 142, preventing the valve body 165 and the valve shaft 168 from falling, and causing the valve body 165 to perform a reliable opening / closing operation. be able to.
[0094]
By the way, when the diaphragm 146, the valve shaft 168, and the valve body 165 in the secondary pressure reducing valve 31 are in a natural state in which the diaphragm 146 avoids the action of external force when assembled to the valve housing 140, the rubber seal of the valve body 165 is provided. The valve body 165 is seated on the valve seat 163 in response to the action of the gas pressure in the pressure acting chamber 148 communicated with the decompression chamber 147. When the diaphragm 146 is bent as described above, the diaphragm 146 exhibits a resilient force in the same direction as the spring force of the coil spring 196, that is, in a direction opposite to the force in the valve closing direction due to the gas pressure in the decompression chamber 147. It will bend to the spring chamber 149 side. Therefore, when the valve body 165 is further separated from the valve seat 163 to increase the gas flow rate, the elastic force exerted by the diaphragm 146 against the force in the valve closing direction due to the gas pressure of the decompression chamber 147 is reduced. It is possible to suppress the resilience exerted by the diaphragm 146 from adversely affecting the responsiveness as much as possible, and the pressure in the decompression chamber 147 is not controlled to a lower value even if the gas flow rate is increased.
[0095]
Moreover, the diaphragm 146 has a ring-shaped outer peripheral seal portion 146a sandwiched by the valve housing 140, a valve shaft connecting portion 146b to which the valve shaft 168 is connected, and a cross-sectional shape that swells toward the spring chamber 149 side. It has a flexible part 146c that is arranged on the inner side of the seal part 146a, and in the natural state, the inner peripheral part of the flexible part 146c is offset by a set offset amount e on the decompression chamber 147 side than the outer peripheral part. It is formed in the shape made. For this reason, when the diaphragm 146 is assembled to the valve housing 140 in a natural state, the inner peripheral portion of the bending portion 146c of the diaphragm 146, that is, the central side where the valve body 165 is connected via the valve shaft 168 is the bending portion 146c. Therefore, when the diaphragm 146 is assembled to the valve housing 140 in a natural state, the state in which the valve body 165 is separated from the valve seat 163 can be easily revealed. As a result, the assembly work of the diaphragm 146 is facilitated.
[0096]
Further, in the secondary pressure reducing valve 31, an end wall 143b is provided at the end of the cylindrical portion 143a constituting a part of the valve housing 140 on the opposite side to the diaphragm 146, and is integrally connected to the end wall 143b. An adjustment screw 188 capable of adjusting the spring load of the coil spring 196 according to the axial advance / retreat position is screwed onto the support cylinder portion 184 disposed coaxially in the cylindrical portion 143a. Therefore, the spring load of the coil spring 196 can be adjusted simply by screwing the adjustment screw 188 into the support cylinder portion 184 and adjusting the advance / retreat position, and the number of parts necessary for adjusting the spring load of the coil spring 196 can be reduced. It is possible to reduce the number of assembly steps.
[0097]
In addition, the support cylinder portion 184 is provided with an inner small diameter hole 185 and an outer large diameter hole 186 coaxially, and the adjustment screw 188 is fitted in the small diameter hole 185 and the small diameter hole. An annular seal member 189 elastically contacting the inner surface of 185 is provided with a small-diameter shaft portion 188a attached to the outer surface on the distal end side, and the large-diameter hole 186 is inserted when the adjusting screw 188 is inserted into the support cylinder portion 184. It is possible to avoid as much as possible that the seal member 189 is damaged by the internal thread 187 provided on the inner surface of the seal member.
[0098]
Further, since the adjustment screw 188 is screwed into the support cylinder portion 184 until the outer end thereof is inward of the outer surface of the end wall 143b, the adjustment screw 188 does not protrude from the outer surface of the end wall 143b. This can contribute to downsizing of the secondary pressure reducing valve 31.
[0099]
Further, a recess 192 is formed at the outer end of the large-diameter hole 886 with the outer end of the large-diameter shaft portion 188b included in the adjustment screw 188 as a closed end, and the recess 192 is filled with the filler 193. By solidifying, it is possible to prevent the adjustment screw 188 from rotating and to prevent erroneous operation while eliminating the need for a lock nut or cap. In particular, the filler 193 enters the engagement recess 191 at the outer end of the adjustment screw, so that the adjustment screw 188 The detent can be made even more reliable.
[0100]
Moreover, the female screw 187 to which the adjusting screw 188 is screwed is engraved in the large-diameter hole 186 with a part thereof facing the concave portion 192, and the filler 193 filled in the concave portion 192 is formed in the thread groove of the female screw 187. By being inserted, the filler 193 can be securely held in the recess 192, and the filler 193 efficiently penetrates into the screwed portion between the male screw 190 of the adjustment screw 188 and the female screw 187 of the large-diameter hole 186. And the rotation of the adjusting screw 188 can be more reliably prevented.
[0101]
FIG. 23 and FIG. 24 show a second embodiment of the present invention, and parts corresponding to the first embodiment are given the same reference numerals.
[0102]
The high-pressure filter 39, the electromagnetic shut-off valve 40, and the primary pressure-reducing valve 41 are disposed in the common regulator body 38B, whereby the regulator RB is configured.The
[0103]
The end surface of the regulator body 38B is formed as a flat mounting surface 201 on the side opposite to the side where the primary pressure reducing valve 41 is disposed. One end of the regulator body 38B is connected to the pressure reducing chamber 94 of the primary pressure reducing valve 41. The other end of the outlet passage 133 'provided in the regulator body 38B is opened.
[0104]
The body 202A shown in FIG. 23 and the body 202B shown in FIG. 23 are alternatively and detachably attached to the attachment surface 201, and the bodies 202A and 202B are attached to the bodies 202A and 202B, respectively. Are respectively provided with low-pressure passages 203 and 203 that communicate with the outlet passage 133 'when attached to the attachment surface 201.
[0105]
One body 202A shown in FIG. 23 is provided with a relief valve 204. The relief valve 204 has a valve hole 205 communicating with the low-pressure passage 203 at the tip and is fixed to the body 202A. 206, a valve body 208 having a rubber seal 207 at the front end capable of closing the valve hole 205, and a spring 209 for urging the valve body 208 in a direction to close the valve hole 205 with the rubber seal 207 are housed. The valve housing 206 and the valve body 208 are formed so that the CNG from the low pressure passage 203 can be opened to the outside when the valve hole 205 is opened.
[0106]
In other words, the relief valve 204 functions to open and release CNG to the atmosphere when the pressure of the low pressure passage 203, that is, the output pressure of the primary pressure reducing valve 41 becomes a set pressure determined by the spring 209, for example, 1.65 MPa or more. .
[0107]
A pressure switch 42 is attached to the other body 202B shown in FIG. 24. The pressure switch 42 is configured such that the pressure in the low pressure passage 203, that is, the output pressure of the primary pressure reducing valve 41 is, for example, a preset set pressure, for example, 1 The switching mode is changed according to the pressure of 65 MPa or more, and a signal for shutting off the electromagnetic shut-off valve 40 is output.
[0108]
According to the second embodiment, the output pressure of the primary pressure reducing valve 41 becomes equal to or higher than the set pressure in preventing the high pressure higher than the set pressure from acting on the secondary pressure reducing valve 31 (see the first embodiment). In order to shut off the electromagnetic shut-off valve 40 in response to the use of a relief valve 204 that releases part of the CNG output from the primary pressure reducing valve 41 or when the output pressure of the primary pressure reducing valve 41 exceeds a set pressure. The pressure switch 42 can be arbitrarily selected and either the relief valve 204 or the pressure switch 42 can be selected and connected to the regulator RB. The versatility can be increased.
[0109]
Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various design changes can be made without departing from the present invention described in the claims. It is.
[0110]
【The invention's effect】
As described above, according to the first aspect of the present invention, the structure for adjusting the spring load of the coil spring can be configured with a small number of parts and the number of assembly steps can be reduced. In addition, it is possible to avoid the sealing member from being damaged as much as possible when the adjustment screw is inserted into the support cylinder, and the adjustment screw does not protrude from the outer surface of the end wall, contributing to the downsizing of the gas pressure reducing valve. can do. In addition, the lock screw and cap are not required, and the adjustment screw can be prevented from rotating and erroneous operation can be prevented. In particular, the filler can enter the engagement recess at the outer end of the adjustment screw, making the adjustment screw more reliable. Can be.
[0111]
According to the second aspect of the present invention, the filler can be reliably held in the recess, and the adjustment screw can be more reliably prevented from rotating.
[Brief description of the drawings]
FIG. 1 is a diagram schematically showing a configuration of a fuel gas supply apparatus according to a first embodiment.
FIG. 2 is a plan view showing a state in which the fuel gas supply device is mounted on a vehicle.
FIG. 3 is a side view of the regulator.
4 is a plan view of the regulator as viewed from the direction of arrow 4 in FIG. 3. FIG.
FIG. 5 is a bottom view of the regulator as viewed from the direction of arrow 5 in FIG. 3;
6 is a cross-sectional view taken along line 6-6 of FIG.
7 is a cross-sectional view taken along line 7-7 of FIG.
FIG. 8 is an enlarged longitudinal sectional view of an electromagnetic shut-off valve.
FIG. 9 is an enlarged longitudinal sectional view of a primary pressure reducing valve.
FIG. 10 is a plan view of a leaf spring provided in the primary pressure reducing valve.
11 is a cross-sectional view taken along the line 11-11 in FIG.
12 is a side view of the secondary pressure reducing valve, as viewed from the direction of arrow 12 in FIG.
13 is a view taken in the direction of arrow 13 in FIG.
14 is a view taken in the direction of arrow 14 in FIG.
15 is a cross-sectional view taken along line 15-15 of FIG.
16 is a cross-sectional view taken along line 16-16 in FIG.
FIG. 17 is an enlarged view of a main part of FIG.
FIG. 18 is a plan view of a partition member provided in the secondary pressure reducing valve.
19 is a cross-sectional view taken along line 19-19 in FIG.
FIG. 20 is an enlarged longitudinal sectional view of a diaphragm provided in the secondary pressure reducing valve.
FIG. 21 is a plan view of a leaf spring included in the secondary pressure reducing valve.
22 is a cross-sectional view taken along line 22-22 of FIG.
FIG. 23 is a cross-sectional view corresponding to FIG. 6 of the second embodiment.
24 is a cross-sectional view corresponding to FIG. 23 with the body replaced. FIG.
[Explanation of symbols]
31 ... Secondary pressure reducing valve as gas pressure reducing valve
140 ... Valve housing
143a ... cylindrical portion
143b ... end wall
146: Diaphragm
147 ... decompression chamber
149 ... Spring chamber
162 ... valve hole
163 ... Valve seat
165 ... Valve
184 ... Supporting cylinder part
185 ... Small hole
186 ... Large-diameter hole
187 ... Female thread
188 ... Adjustment screw
188a ... Small diameter shaft
188b ... Large diameter shaft
189 ... Sealing member
190 ... Male thread
191 ... engaging recess
192 ... recess
193 ... Filler
196: Coil spring

Claims (2)

The peripheral portion of the diaphragm (146) that allows the gas pressure in the decompression chamber (147) to act on one side is sandwiched between the valve housing (140), and the valve hole (162) leading to the decompression chamber (147) is opened at the center. A valve body (165) that can be seated on the valve seat (163) is connected to a central portion of the diaphragm (146), and a spring chamber (149) facing the other surface of the diaphragm (146) includes the valve housing (140). Is formed in a cylindrical portion (143a) provided with an end wall (143b) on the opposite side of the diaphragm (146), and the valve body (165) is separated from the valve seat (163). A coil spring (196) that urges the diaphragm (146) in the direction is housed in the spring chamber (149), is coaxially disposed in the cylindrical portion (143a), and is connected to the end wall (143b). In the gas pressure reducing valve to which the adjusting screw (188) for adjusting the spring load of the coil spring (196) is screwed into the supporting cylinder part (184) according to the axial advance / retreat position, the supporting cylinder part (184) is provided with an inward small-diameter hole (185) and an outer large-diameter hole (186) in which a female screw (187) is engraved at least partially, and is provided coaxially. A small-diameter shaft portion (188a) to which an annular seal member (189) fitted into (185) and elastically contacts the inner surface of the small-diameter hole (185) is mounted on the outer surface, and the female screw (187). A large-diameter shaft portion (188b) provided with an engaging recess (191) capable of engaging with a rotary operation tool is integrally and coaxially connected to the outer end surface of the outer end surface and a male screw (190) to be engaged. Advancing and retracting position of the adjusting screw (188) in the axial direction The outer end surface of the large-diameter shaft portion (188b) is set at a position that is inward of the outer surface of the end wall (143b), and the outer end of the large-diameter shaft portion (188b) is a closed end. A gas pressure reducing valve, wherein a recess (192) formed at an outer end of (186) is filled with a solidifying filler (193). The gas pressure reducing valve according to claim 1, wherein the female screw (187) is engraved in the large-diameter hole (186) with a part thereof facing the recess (192).

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