BREATHER PLUG FOR INSTALLATION ON LIQUID STORAGE TANKS

Abstract

A breather plug for installation on liquid storage tanks has a main body with a hand-operated structure and an assembly structure which are connected. A flow channel penetrates the main body. A pinching part is formed on the radial periphery of the hand-operated structure. The fingers pinch the pinching part to rotate the main body. The assembly structure has a screwing section and a tapping section, so that said the body is installed on the tank body of the liquid storage tank through the assembly structure, allowing air to enter or leave the liquid storage tank through the flow channel. The pinching part is pinched by hand to rotate the main body, and the assembly structure is assembled on the liquid storage tank using the cutting action of the tapping section. As such, operation is easy and unlikely to fail.

Claims

1. (canceled)

2. (canceled)

3. (canceled)

4. (canceled)

5. (canceled)

6. (canceled)

7. (canceled)

8. (canceled)

9. (canceled)

10. (canceled)

11. (canceled)

12. (canceled)

13. (canceled)

14. (canceled)

15. (canceled)

16. (canceled)

17. A breather plug for installation on a tank body of a liquid storage tank, the breather plug comprising: a main body formed of a metal material, said main body having a hand-operated structure axially connected to an assembly structure, said main body having a flow channel extending axially thereinto, said main body having a first side and a second side, the first side being formed on the hand-operated structure, said second side being formed on the assembly structure, the first side and the second side being opposite each other, said flow channel extending to the first side and the second side, said assembly structure having a screwing section and a tapping section, the screwing section being located between the outlet structure and said tapping section, the screwing section being cylindrical, the tapping section being a tapered column, the tapping section having a radial dimension that decreases from the screwing section to the second side, the screwing section having a first screw thread formed on a periphery thereof, the tapping section having a second screw thread formed on a periphery thereof, the second screw thread being a tapping screw thread, the first screw thread and the second screw thread having an identical helix angle and an identical thread pitch, the first screw thread and the second screw thread being connected such that said main body is adapted to be installed on the liquid storage tank through the assembly structure and such that air enters or leaves the liquid storage tank through the flow channel, wherein only the screwing section engages the tank body and the tapping section does not engage the tank body when said main body is fully installed on the tank body; and a pinching part formed around a radial periphery of the hand-operated structure, said pinching part being without a flat surface, said pinching part having a rough microstructure.

18. The breather plug of claim 17, wherein an annular pressing face is formed at an end of the hand-operated structure facing the assembly structure, the annular pressing face having an annular inner edge abutting the assembly structure, the assembly structure having a washer fitted thereover, the washer being formed of an elastic material, the washer being adjacent to the annular pressing face.

19. The breather plug of claim 17, wherein the rough microstructure of said pinching part comprises dents and bulges, the bulges having an outer side away from the flow channel and positioned in a circular boundary, a distance between an outer side of the bulges and an inner side of respective dents along a diameter of the hand-operated structure being less than one millimeter.

20. The breather plug of claim 17, wherein said pinching part has an outer diameter of between 10 millimeters and 16 millimeters.

21. The breather plug of claim 17, wherein the flow channel defines a storage chamber extending to the first side, the storage chamber having an annular abutting surface formed therein.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0015] FIG. 1 is the section view of the known breather structure installed on a liquid storage tank.

[0016] FIG. 2 is the three-dimensional diagram of the operating state of the known breather structure installed on a liquid storage tank.

[0017] FIG. 3 is the stereogram of the Embodiment 1 of the present invention.

[0018] FIG. 4 is the axial section view of the Embodiment 1 of the present invention.

[0019] FIG. 5 is the sectional view (I) of operating state of Embodiment 1 of the present invention installed on a liquid storage tank.

[0020] FIG. 6 is the sectional view (II) of operating state of Embodiment 1 of the present invention installed on a liquid storage tank.

[0021] FIG. 7 is the section view of Embodiment 1 of the present invention installed on a liquid storage tank.

[0022] FIG. 8 is the stereogram of the Embodiment 2 of the present invention.

[0023] FIG. 9 is the stereogram of the Embodiment 3 of the present invention.

[0024] FIG. 10 is the radial section view of the hand-operated structure in the Embodiment 3 of the present invention.

[0025] FIG. 11 is the drawing of partial enlargement of FIG. 10.

[0026] FIG. 12 is the sectional view of the Embodiment 4 of the present invention.

[0027] FIG. 13 is the section view of operating state of the Embodiment 5 the present invention.

DETAILED DESCRIPTION OF THE INVENTION

[0028] As shown in FIG. 3 to FIG. 7, the Embodiment 1 of the aforementioned breather plug which can be installed on a liquid storage tank comprises a main body 20, wherein the main body 20 is made of metal material. The main body 20 comprises a hand-operated structure 21 and an assembly structure 22 which are axially connected. The hand-operated structure 21 and the assembly structure 22 are formed integrally. A flow channel 23 axially penetrates the main body 20. The flow channel 23 penetrates the hand-operated structure 21 and the assembly structure 22. The main body 20 has a first side 24 and a second side 25. The first side 24 is formed on the hand-operated structure 21, the second side 25 is formed on the assembly structure 22, and the first side 24 and the second side 25 are opposite to each other in axial direction of the main body 20. The flow channel 23 extends to the first side 24 and the second side 25.

[0029] The radial periphery of the hand-operated structure 21 forms an annular pinching part 211, so that the fingers 80 pinch the pinching part 211 to rotate the main body 20, to enhance the operation reliability of assembling the main body 20 on the liquid storage tank 90. An annular pressing face 212 is formed at one end of the hand-operated structure 21 facing the assembly structure 22. The annular inner edge of the pressing face 212 abuts on the assembly structure 22. Furthermore, the pinching part 211 without a flat surface is formed around the radial periphery of the hand-operated structure 21, so that the spanner or other forms of hand tools cannot effectively clamp and pull the hand-operated structure 21, the hand-operated structure 21 cannot be rotated with a hand tool, the operation reliability of assembling the main body 20 on the liquid storage tank 90 is enhanced.

[0030] The assembly structure 22 has a screwing section 222 and a tapping section 224. The screwing section 222 axially contacts the tapping section 224. The second side 25 is formed on the tapping section 224. The screwing section 222 is located between the hand-operated structure 21 and the tapping section 224. The screwing section 222 is cylindrical. The tapping section 224 is a tapered column, and the radial dimension of the tapping section 224 decreases from the screwing section 222 to the second side 25. A first screw thread 223 is formed on the periphery of the screwing section 222. The first screw thread 223 is a connecting screw thread. A second screw thread 225 is formed on the periphery of the tapping section 224. The second screw thread 225 is a tapping screw thread. The second screw thread 225 is a continuous screw thread. The first screw thread 223 and the second screw thread 225 have the same helix angle and thread pitch, and the first screw thread 223 and the second screw thread 225 are connected integrally, so that the main body 20 is installed on the tank body 91 of the liquid storage tank 90 through the assembly structure 22, and the air enters or leaves the liquid storage tank 90 through the flow channel 23.

[0031] FIG. 5 to FIG. 7 describe the operation of installing Embodiment 1 on the liquid storage tank 90. A mounting hole 95 penetrates the tank body 91. Let the minimum outside diameter of the second screw thread 225 be Φ3, the outside diameter of the first screw thread 223 be Φ4, the minor diameter of root of the first screw thread 223 be Φ5, the inside diameter of the mounting hole 95 be Φ6, 06 is a little larger than Φ3, and Φ6 smaller than Φ4 is preferred.

[0032] The fingers 80 pinch the pinching part 211, so that the tapping section 224 enters the mounting hole 95 and rotates the main body 20, the second screw thread 225 cuts the hole wall 952 of the mounting hole 95. As the tapping section 224 enters the space inside the liquid storage tank 90 gradually (not shown in the figure), the hole wall 952 is processed by the tapping section 224 to form an internal thread 954 and guide the main body 20. Afterwards, the screwing section 222 enters the mounting hole 95, and the first screw thread 223 engages with the internal thread 954, the tapping section 224 enhances the handiness of installing the main body 20 on the tank body 91 through the screwing section 222.

[0033] When the Embodiment 1 is installed on the tank body 91, the tank body 91 is processed by using a tool to form the mounting hole 95, the user can pinch the pinching part 211 to rotate the main body 20 without any other tools, and then the assembly structure 22 can be assembled on the tank body 91 under the cutting action of the tapping section 224 on the hole wall 952, the operation is easy and unlikely to fail.

[0034] On the other hand, with the formation of the pinching part 211, the spanner or other forms of hand tools cannot effectively clamp and pull the hand-operated structure 21. When the main body 20 is installed on the tank body 91, the resistance of the tank body 91 to the assembly structure 22 makes the assembly structure 22 penetrate into the space continuously, preventing the tapping section 224 from overcutting the hole wall 952, the internal thread 954 will not be destroyed by the assembly structure 22, the screwing reliability of the first screw thread 223 and the internal thread 954 is enhanced.

[0035] A washer 30 is fitted over the assembly structure 22. The washer 30 is made of elastic material, and the washer 30 is adjacent to the pressing face 212. When the main body 20 is installed on the tank body 91, the pressing face 212 and the tank body 91 oppositely press the washer 30, so as to form a better discharge stop effect, preventing the liquid in the liquid storage tank 90 from leaking out between the assembly structure 22 and the hole wall 952. The assembly structure 22 is unlikely to get loose from the mounting hole 95 due to the elasticity of the washer 30.

[0036] The outside diameter Φ7 of the pinching part 211 is 10 mm-16 mm, the user is easy to pinch the pinching part 211 with the fingers 80, but difficult to grab the pinching part 211 with palm. The user will not apply excessive force to the pinching part 211, avoiding excessive rotation of the main body 20. In this case, the outside diameter Φ7 of the pinching part 211 is 14 mm.

[0037] As shown in FIG. 8, the main difference of Embodiment 2 from Embodiment 1 is that the pinching part 211 forms a rough microstructure 27, so that the surface friction of the pinching part 211 is increased. The microstructure 27 is formed by sandblasting, peening or etching the pinching part 211.

[0038] As shown in FIG. 9 to FIG. 11, the main difference of Embodiment 3 from Embodiment 2 is that the microstructure 27 is formed by rolling or etching the pinching part 211. The microstructure 27 comprises several dents 272 and several bulges 274. A virtual boundary 276 is defined, the boundary 276 is circular, and the center of the boundary 276 is exactly in the radial center of the hand-operated structure 21. The outer side of the bulges 274 far from the flow channel 23 is within the boundary 276. Along the diameter of the hand-operated structure 21, the distance D between the outer side of the bulge 274 and the inner side of the dent 272 smaller than 1 mm is a better implementation option.

[0039] Embodiment 2 and Embodiment 3 use the microstructure 27 to increase the relative friction between the fingers 80 and the pinching part 211, the user is easier to pinch the pinching part 211 with the fingers 80 to rotate the main body 20.

[0040] As shown in FIG. 12, the main difference of Embodiment 4 from Embodiment 1 is that the Embodiment 4 has a blocking structure 40, the blocking structure 40 is disposed on the main body 20, so as to interrupt the connection between the flow channel 23 and external environment through the first side 24.

[0041] The flow channel 23 expands to form a storage chamber 232, the storage chamber 232 extends to the first side 24, an annular abutting surface 234 is formed inside the storage chamber 232.

[0042] The blocking structure 40 comprises a limiting piece 41, a stop block 42 and a spring 43, wherein the limiting piece 41 is disposed in the storage chamber 232, a chamber 412 and a channel 414 are formed inside the limiting piece 41. The abutting surface 234 is located in the chamber 412. The chamber 412 communicates with the channel 414. The channel 414 extends to the first side 24. An annular limiting surface 416 is formed between the chamber 412 and the channel 414. The stop block 42 and the spring 43 are disposed in the chamber 412. The outside diameter of the stop block 42 is smaller than the inside diameter of the chamber 412. Both ends of the spring 43 prop the stop block 42 and the abutting surface 234 respectively, so that the stop block 42 props the limiting surface 416 to interrupt the connection between the chamber 412 and the channel 414.

[0043] The general situation, the stop block 42 interrupts the connection between the chamber 412 and the channel 414, the outside foreign materials cannot enter the liquid storage tank 90 through the flow channel 23. When the liquid storage tank 90 is tilted to discharge the liquid in the liquid storage tank 90, the pressure inside the space drops as the liquid flows out, forming a sucking action on the stop block 42, the stop block 42 moves towards the space, the stop block 42 leaves the limiting surface 416, the chamber 412 communicates with the channel 414, the air can enter the liquid storage tank 90 through the channel 414, the chamber 412 and the flow channel 23, and the liquid flows out smoothly.

[0044] Furthermore, the inside diameter of the limiting surface 416 decreases from the chamber 412 to the channel 414, so that the limiting surface 416 is conical. The stop block 42 has a conical end 422, so that the end 422 props the limiting surface 416, enhancing the reliability of the stop block 42 obstructing air. The end 422 and the limiting surface 416 have the same coning angle, so the end 422 adhering to the limiting surface 416 is a better implementation option.

[0045] The blocking structure 40 can be provided with a conical limiting surface 416 or a conical end 422, so as to form a different embodiment based on Embodiment 4.

[0046] As shown in FIG. 13, the main difference of Embodiment 5 from Embodiment 1 is that the Embodiment 5 has a blocking structure 40, the blocking structure 40 has a close over 45, the close over 45 is removably installed on the first side 24, so as to interrupt the connection between the flow channel 23 and external environment through the first side 24.