One-gauge one-turn regulator manifold

Abstract

A one-gauge one-turn regulator manifold includes a manifold body, a spring set, a knob set, an annular dial and one inlet pressure gauge. The outlet pressure is selected and adjusted by turning a control knob without a pressure gauge. The control knob with a marker indicating the outlet pressure from zero to maximum is rotatable within one turn. The knob set contains one adjusting screw which is used to fine-tune the pressure, and thus the outlet air pressure is calibrated as expected. The annular dial with pressure tick marks is located between the control knob and the manifold body. The outlet pressure is easy to selected and controlled by turning the knob to the desired pressure makers on the dial without the pressure gauge.

Claims

1. A one-gauge one-turn regulator manifold comprising: a manifold body having a passage; an inlet side communicating with the passage; and an outlet side communicating with the passage; a spring set located in the manifold body and having a poppet spring; a poppet; a poppet seat; an o-ring; a piston; a sealing ring; a range spring; and a spring cap; a knob set mounted on the outlet side of the manifold body, mounted on the spring set, and having an adjusting screw; a nut; a knob shell having an internal thread engaged with an external thread of the manifold body; a knob cap; an indicator; and a pin inserted radially into the knob shell; an annular dial combined with an outer side of a circumference of the knob set and having multiple tick marks marked on the annular dial; and an inlet pressure gage mounted on the inlet side of the manifold body.

2. The one-gauge one-turn regulator manifold as claimed in claim 1, wherein the rotation angle of the knob set is above 180 and less than 350.

3. The one-gauge one-turn regulator manifold as claimed in claim 1, wherein the pitch of the external thread of the manifold body ranges from 3 to 5 millimeters.

4. The one-gauge one-turn regulator manifold as claimed in claim 1, wherein laps of the external thread of the manifold body are within the range of 3 to 6 turns.

5. The one-gauge one-turn regulator manifold as claimed in claim 1, wherein the poppet spring has a spring constant in the range of 1.0 to 1.5 N/mm, and the range spring has a spring constant within the range of 150 to 160 N/mm.

6. The one-gauge one-turn regulator manifold as claimed in claim 1, wherein said adjusting screw is a circular arc, and a center of the spring cap is a circular cavity.

7. The one-gauge one-turn regulator manifold as claimed in claim 1, wherein an anaerobic adhesive is added between said adjusting screw and said nut to augment the engagement.

8. The one-gauge one-turn regulator manifold as claimed in claim 1, wherein a maximum output pressure value is 135 psi when the knob set is adjusted to the maximum.

9. The one-gauge one-turn regulator manifold as claimed in claim 1, wherein said annular dial is labeled by adding patterns or texts.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of a one-gauge one-turn regulator manifold in accordance with the present invention;

(2) FIG. 2A is a top view of the one-gauge one-turn regulator manifold in FIG. 1;

(3) FIG. 2B is a cross sectional side view of the one-gauge one-turn regulator manifold in FIG. 1;

(4) FIG. 3 is an exploded perspective view of the one-gauge one-turn regulator manifold in FIG. 1A;

(5) FIG. 4A is an operational perspective view of the one-gauge one-turn regulator manifold in FIG. 1;

(6) FIG. 4B is another operational perspective view of the one-gauge one-turn regulator manifold in FIG. 1;

(7) FIG. 5A is a cross sectional side view of a knob set of the one-gauge one-turn regulator manifold in FIG. 1; and

(8) FIG. 5B is a top view in partial section of a knob set of the one-gauge one-turn regulator manifold in FIG. 1.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENT

(9) With reference to FIGS. 1 to 5, a one-gauge one-turn regulator manifold in accordance with the present invention includes a manifold body 10, a spring set 20, a knob set 30, an annular dial 40, and an inlet pressure gauge 50. The one-gauge one-turn regulator manifold provides a quick selection and a stable output of outlet pressure by directly turning a knob shell 33 without using any outlet pressure gauge. All components are also illustrated with reference to FIG. 3.

(10) The manifold body 10 is a key part for the combination of the regulator manifold in accordance with the present invention, and the manifold body 10 may be made of an aluminum alloy or a zinc alloy. With reference to FIGS. 2 and 3, the manifold body 10 includes an inlet side 10a and an outlet side 10b for compressed air, the inlet pressure gauge 50 is mounted on the inlet side 10a for showing the pressure value of the compressed air, and the air flows from the inlet side 10a and passes through a middle portion of the manifold body 10, wherein the spring set 20 is used to adjust air pressure, and then the air passes through the outlet side 10b of the manifold body 10. The output air pressure is adjusted by changing the compression and extension of the spring set 20. To compress the spring set 20 may enlarge a valve opening for a higher output pressure. Alternatively, to loosen the spring may lessen a valve opening for a lower output pressure.

(11) With reference to FIG. 43 the manifold body 10 is integrally formed with an external thread 101 having a pitch and a knob stop 102. The external thread 101 is fitted with the knob shell 33 having an internal thread to form a rotary mechanism of the regulator manifold. The knob stop 102 prevents the knob shell 33 from over-rotating and keeps the operating pressure under a limit.

(12) The spring set 20 is the key mechanism for the pressure stability of the regulator manifold in accordance with the present invention. As shown in FIGS. 2 and 3, the spring set 20 has a poppet spring 21, a poppet 22, a poppet seat 23, an O-ring 24, a piston 25, a sealing ring 26, a range spring 27, and a spring cap 28. The spring set 20 is installed inside the middle portion of the manifold body 10. Preferably, by using the materials which are resistant to both corrosion and weariness for these components, the accuracy of output pressure is well controlled. For example, the material of the poppet spring 21 is preferably stainless steel SUS301, and the spring constant of the poppet spring 21 is within the range of 1.0 N/mm to 1.5 N/mm, preferably 1.2 N/mm. The material of the range spring 27 is preferably 65Mn spring steel, and the spring constant of the range spring 27 is within the range of 150 N/mm to 160 N/mm, preferably 154 N/mm.

(13) The knob set 30 is a key design for ease in use of the regulator manifold. With reference to FIGS. 2 to 5, a preferred embodiment of the knob set 30 includes an adjusting screw 31, a nut 32, the knob shell 33, a knob cap 34, an indicator 35, and a pin 36. The knob shell 33 has an internal thread 301 engaged with an external thread 101 of the manifold body 10, and the pin 36 is inserted into the knob shell 33.

(14) Please refer to FIG. 2 and FIG. 4. The adjusting screw 31 in the knob set 30 directly abuts against the spring cap 28 of the spring set 20, thereby transferring the force from the knob set 30 to the entire spring set 20. The output pressure can be easily adjusted by rotating the knob set 30 manually, the output pressure will be zero when the knob set 30 is rotated counterclockwise until the pin 36 is stopped by the end of the internal thread 101, and the output pressure will be the maximum when the knob set 30 is rotated clockwise until the knob shell 33 is stopped by the knob stop 102, so that user can adjust the air pressure in full range (zero to maximum).

(15) Please refer to FIG. 5. An object of the present invention is to provide a full-range adjustment of output air pressure within one revolution. Preferably, the internal thread 301 of the knob shell 33 and the external thread 101 of the manifold body 10 are adapted by coarse-grade threads, and the thread pitch would be large enough to cover a full-range adjustment of the output pressure. The pin 36 and the knob stop 102 are properly located to limit a range of pressure adjustment. The external thread 101 of the manifold body 10 should have a sufficient number of turns and the pitch should not be too wide to prevent the knob shell from rotating by mechanical vibrations. It has been recommended by the inventors of the present invention that the number of turns for the external thread 101 of the manifold body 10 should fall within the range of 3 to 6 turns, and the thread pitch should fall within the range of 2 to 6 mm, preferably 3 to 5 mm. The pitch of the internal and external threads should be correlated to the spring constant (force constant) of the range spring 27 and the poppet spring 21.

(16) With reference to FIG. 5, the adjusting screw 31 has a round tip to prevent the spring set 20 from being misaligned while rotating the knob shell. The spring cap 28 also has a circular recess, so that the torsional friction between the adjusting screw 31 and the spring cap 28 is reduced for continuous and smooth adjustment. The calibration of output pressure is operated by rotating the adjusting screw 31 through the nut 32, and the adjusting screw 31 and the nut 32 are engaged with fine-grade threads. Besides, an anaerobic adhesive is applied between the adjusting screw 31 and the nut 32 to ensure that the calibration is reliable and the output pressure is stable under the vibration of the air compressor.

(17) The annular dial 40 is a key design for the selection of output pressure in the regulator manifold. Please refer to FIG. 2, which shows a preferred embodiment of an annular dial 40 of the present invention. The annular dial 40 is located around the knob set 30 on the manifold body 10, and has tick marks 401 to indicate the outlet pressure. The indicator 35 can be aligned with a specific tick mark 401 by turning the knob shell 33. The output pressure can be adjusted in a full range (zero to maximum) by turning the knob shell within one revolution (less than 360), preferably less than 350. The operation range of the knob shell is more than 180 to provide a minimum resolution (psi/degree) for the pressure adjustment. The tick marks 401 can also be complemented by use of texts or icons, for example, 30 psi for air guns, 90 psi for pneumatic tools which is easy to select by switching the indicator 35 to the icon or text displayed on the annular dial 40.

(18) The outlet pressure gauge 50 is the only pressure gauge in the regulator manifold of the present invention. Referring to FIG. 2, the pressure gauge 50 which is connected to the inlet side 10a of the manifold body 10 shows the pressure value of the input compressed gas, and is applicable with a pressure range of 30 to 180 psi.

(19) This newly invented one-gauge one-turn regulator manifold can be connected with an air compressor, a hydraulic pipe, and the like to adjust the output of the gas pressure, and is suitable for all kinds of pneumatic tools and pneumatic fittings. The invention can be employed to the input gas pressure as high as 145 psi, or 10 kg/cm.sup.2, or 10 bar. The output gas pressure may be zero at the time of valve clearance, up to 145 psi at maximum valve opening, or 10 kg/cm.sup.2, or 10 bar. The following three embodiments illustrate the efficacy of the present invention in terms of assembly consistency, operational convenience and pressure stability.

Example 1: Assembly Consistency Quality Test

(20) As shown in FIG. 1 to FIG. 5, all components of the one-gauge one-turn regulator manifold are made of the same material: the internal thread of the manifold body pitch is 4 mm, the K value of the range spring is 154 N/mm, and the K value of the poppet spring is 1.2 N/mm.

(21) Preferably, 111 pieces of calibrated assemblies were tested for the rotation angle of the corresponding knob with different output pressures (30, 60, 90, 120, 135 psi) and the measured statistical analysis was recorded in Table 1.

(22) The results show that the quality of assemblies is the same, and the relative standard deviation (RSD) of the experimental data is within 5%.

(23) TABLE-US-00001 TABLE 1 Statistical analysis of the rotation angle of the corresponding knob with different output pressures Sample Output Pressure(psi) No. 30 60 90 120 135 NO. 01 134 204 268 321 341 NO. 02 130 197 260 321 341 NO. 03 132 203 265 325 345 NO. 04 130 195 264 324 347 NO. 05 130 195 260 315 338 NO. 06 131 194 265 317 339 NO. 07 128 194 260 320 341 NO. 08 133 193 260 321 338 NO. 09 132 197 264 324 338 NO. 10 134 203 267 328 343 NO. 11 137 198 266 314 345 NO. 12 137 202 269 319 338 NO. 13 138 198 260 320 341 NO. 14 131 197 266 323 338 NO. 15 130 196 266 323 341 NO. 16 131 197 264 324 341 NO. 17 135 204 267 326 338 NO. 18 136 205 270 325 341 NO. 19 133 198 263 321 341 NO. 20 131 197 260 320 341 NO. 21 130 193 260 320 341 NO. 22 135 203 268 327 338 NO. 23 135 200 267 322 341 NO. 24 134 198 265 325 341 NO. 25 133 199 270 327 338 NO. 26 135 200 262 315 338 NO. 27 132 199 266 324 341 NO. 28 135 200 265 322 338 NO. 29 130 196 259 317 338 NO. 30 135 198 261 323 341 NO. 31 136 202 264 317 341 NO. 32 135 201 265 320 338 NO. 33 130 197 264 326 341 NO. 34 130 192 258 320 338 NO. 35 130 200 270 321 341 NO. 36 133 199 268 315 338 NO. 37 135 200 263 312 338 NO. 38 130 202 264 318 338 NO. 39 130 193 258 324 341 NO. 40 137 199 263 315 338 NO. 41 130 198 261 317 343 NO. 42 130 192 260 317 338 NO. 43 130 193 260 322 338 NO. 44 130 195 262 320 338 NO. 45 130 194 258 320 338 NO. 46 131 195 258 319 341 NO. 47 130 195 258 320 341 NO. 48 129 194 257 317 338 NO. 49 132 196 258 315 341 NO. 50 135 200 262 319 338 NO. 51 130 195 260 320 338 NO. 52 137 200 261 318 341 NO. 53 130 195 258 320 341 NO. 54 133 197 261 316 341 NO. 55 132 197 258 317 341 NO. 56 135 203 267 320 338 NO. 57 129 195 263 320 338 NO. 58 132 195 260 319 338 NO. 59 130 197 258 315 335 NO. 60 129 195 260 317 341 NO. 61 130 197 260 322 338 NO. 62 132 197 267 315 338 NO. 63 130 202 262 318 341 NO. 64 132 196 262 322 338 NO. 65 138 203 265 318 338 NO. 66 129 195 262 323 341 NO. 67 131 200 260 317 338 NO. 68 133 197 265 318 341 NO. 69 135 202 268 323 338 NO. 70 135 198 261 315 341 NO. 71 131 195 262 320 341 NO. 72 130 195 260 319 338 NO. 73 135 200 265 317 338 NO. 74 132 200 266 320 341 NO. 75 132 197 258 315 338 NO. 76 130 195 259 317 338 NO. 77 137 202 262 315 338 NO. 78 135 198 260 316 341 NO. 79 135 201 264 326 338 NO. 80 135 200 267 319 338 NO. 81 130 201 270 318 341 NO. 82 130 198 261 321 341 NO. 83 135 198 258 317 343 NO. 84 132 200 266 321 338 NO. 85 130 199 261 317 338 NO. 86 130 203 266 316 338 NO. 87 133 199 260 318 338 NO. 88 132 199 270 325 338 NO. 89 135 198 261 319 338 NO. 90 131 200 267 325 341 NO. 91 133 198 260 319 341 NO. 92 135 203 263 320 341 NO. 93 130 202 267 322 338 NO. 94 132 203 266 322 345 NO. 95 130 198 262 316 341 NO. 96 132 201 265 316 343 NO. 97 130 199 262 318 338 NO. 98 130 197 261 319 338 NO. 99 132 201 263 323 343 NO. 100 135 200 265 319 338 NO. 101 132 203 267 315 341 NO. 102 132 197 259 318 338 NO. 103 133 201 270 321 338 NO. 104 130 195 260 314 338 NO. 105 132 197 263 320 341 NO. 106 134 198 263 324 343 NO. 107 132 198 264 321 338 NO. 108 131 202 264 324 338 NO. 109 132 203 265 322 343 NO. 110 134 202 260 321 345 NO. 111 131 196 265 322 338 Average 132.3 198.4 263.0 319.8 339.7 Standard 2.4 3.0 3.4 3.4 2.1 Deviation Max. 138 205 270 328 347 Min. 128 192 257 312 335 Difference 10 13 13 16 12

Example 2: Operational Convenience Comparison Test

(24) Compared with a conventional two-gauge regulator manifold, the one-gauge one-turn regulator manifold of the present invention takes less time in adjusting output pressure from zero to a required pressure (30, 60, 90, 120, 135 psi). The time recorded is shown in Table 2. The result proves that the present invention has the advantages of both convenience and efficiency.

(25) TABLE-US-00002 TABLE 2 Comparison of the time required to adjust to different output pressures Output Pressure (psi) Test Sample 30 60 90 120 135 The Invention 5 6 8 9 9 (One gauge) The 6 12 17 22 21 Conventional (Two gauges) Time Saved 1 6 9 13 12

Example 3: Pressure Stability Comparison Test

(26) At the same input air pressure (135 psi), connect the outlet of the regulator manifolds to the flow meters of the same type, set the flow to the same value, and begin to observe output pressure fluctuations during 120 seconds interval. The results show that the pressure fluctuation of the invention is smaller than that of the conventional two-gauge regulator manifold, as shown in Table 3. It is proved that the pressure output of the invention is stable and is a great improvement over the conventional one.

(27) TABLE-US-00003 TABLE 3 Comparison of output pressure (psi) stability at the same input and output conditions Test 60 seconds interval 120 seconds interval Sample No Max. Min. Difference Max. Min. Difference The Invention 1 51.8 51.5 0.3 51.9 51.5 0.4 (One gauge) 2 52.6 52.1 0.5 52.7 52.1 0.6 3 52.2 51.6 0.6 52.3 51.6 0.7 Compared to the conventional two-gauge regulator: smaller output pressure fluctuation The 1 47.5 46.4 1.1 47.5 46.4 1.1 Conventional 2 48.5 47.4 1.1 48.5 46.8 1.7 (Two gauges) 3 48.1 46.5 1.6 48.1 45.8 2.3 Compared to the invention: bigger output pressure fluctuation

(28) Even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only, and changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.