阅读说明：本技术 集水器 (Water collector ) 是由 向振良 刘科志 于 2018-06-25 设计创作，主要内容包括：本发明乃一种集水器,其至少包括有一第一气室部及一第二气室部,该第一气室部底部外具一接管,第一气室部内具一进气导管,该接管与进气导管二者管内径并为相贯通,第二气室部顶部外具一接管,第二气室部内具一出气导管,该接管与出气导管二者管内径并为相贯通,且出气导管的前端并具较大内管径的前端部；第一气室部与第二气室部二者组接结合后,第二气室部中出气导管的前端部管口将远离于进气导管的管口,让进气导管输出的氧气不至于直接流进于出气导管中而直接对外输出,如此使该含有水气的氧气可于第一气室部及第二气室部中增加留置时间,而有助于该氧气中水份的凝结动作,以有效将氧气中多数的水份予以去除。(The invention relates to a water collector, which at least comprises a first air chamber part and a second air chamber part, wherein the bottom of the first air chamber part is externally provided with a connecting pipe, the first air chamber part is internally provided with an air inlet guide pipe, the inner diameters of the connecting pipe and the air inlet guide pipe are communicated, the top of the second air chamber part is externally provided with a connecting pipe, the second air chamber part is internally provided with an air outlet guide pipe, the inner diameters of the connecting pipe and the air outlet guide pipe are communicated, and the front end of the air outlet guide pipe is provided with a front end part with a larger inner diameter; after the first air chamber part and the second air chamber part are combined, the front end pipe orifice of the air outlet guide pipe in the second air chamber part is far away from the pipe orifice of the air inlet guide pipe, so that the oxygen output by the air inlet guide pipe is not directly flowed into the air outlet guide pipe and is directly output outwards, and therefore the retention time of the oxygen containing moisture in the first air chamber part and the second air chamber part can be prolonged, the condensation action of the moisture in the oxygen is facilitated, and most of the moisture in the oxygen is effectively removed.)

1. A kind of water collector, at least include a first air chamber portion and a second air chamber portion, this first air chamber portion and second air chamber portion can be assembled and combined, and all become one end and is the hollow cylinder that the closed end is open-ended, the first air chamber portion bottom has a connecting pipe outside, the first air chamber portion has an air inlet conduit, and the pipe internal diameter of the connecting pipe and air inlet conduit are and link up, the second air chamber portion top has a connecting pipe outside, the second air chamber portion has an air outlet conduit, the pipe internal diameter of the connecting pipe and air outlet conduit are and link up, characterized by that: the front end of the air outlet conduit of the second air chamber part is provided with a front end part with a larger inner diameter.

2. The manifold of claim 1, wherein the inlet conduit of the first plenum section is offset from the outlet conduit of the second plenum section after the first and second plenum sections are assembled.

3. The water collector as claimed in claim 1, wherein the upper outer edge of the first chamber portion forms a neck portion with a smaller outer diameter, and a groove is formed at the bottom of the neck portion, and a sealing ring is fitted in the groove.

4. A collector according to claim 3, wherein the neck portion has at least two channels formed therein in the axial direction of the first chamber portion, the channels terminating in the neck portion beginning at the upper end edge of the neck portion.

5. A collector according to claim 4, characterised in that the termination of the channel extends to form a rebate in the radial direction of the neck.

6. The manifold of claim 1, wherein the interior of the front portion joins the outlet conduit to form an annulus.

7. The manifold of claim 1, wherein the front end portion is separate from the outlet conduit and is adapted to be integrated therewith.

8. The manifold of claim 1, wherein the front end portion is integrally formed with the outlet conduit.

9. A manifold according to claim 1 wherein the front end nozzle extends beyond the lower edge of the second chamber portion.

10. The manifold of claim 1, wherein the lower end edge of the second chamber portion defines a collar portion having a larger inner diameter, and the inner wall of the second chamber portion is attached to the collar portion and defines at least two protrusions.

Technical Field

The present invention relates to a water collector, and more particularly to a water collector for oxygen output of an oxygen generator, which can remove a large amount of moisture from the output oxygen for the subsequent breathing of the oxygen generator.

Background

Therefore, many oxygen generating devices can effectively generate oxygen, and the generated oxygen can be output externally and then can be breathed by people, thereby promoting the physical health of the people or being used for other purposes.

However, when the oxygen generating apparatus outputs oxygen, the output oxygen contains a large amount of water therein, and in order to remove a large amount of water entrained in the oxygen, a water collector is added in the output pipeline, and the water collector is used to collect and remove the water entrained in the oxygen.

As shown in figs. 1 and 2, the conventional water collector 1 mainly has a first air chamber 11 and a second air chamber 12; the bottom of the first air chamber 11 is provided with a connecting pipe 111, the connecting pipe 111 can be assembled with an oxygen gas pipe 2 for oxygen transportation of the oxygen making equipment, and the connecting pipe 111 is communicated with an air inlet duct 112 in the first air chamber 11; in addition, the top of the second air chamber 12 has a connection tube 121, the connection tube 121 can be connected to another oxygen gas tube 3 for delivering oxygen, and the connection tube 121 is connected to an air outlet tube 122 inside the second air chamber 12. The first and second air chambers 11 and 12 can be combined into a whole, and after the combination, the first and second air chambers 11 and 12 are isolated from the outside, and the inner spaces of the two are communicated.

In application, oxygen from the oxygen generating apparatus will circulate through the pipe 111 and the air inlet conduit 112 into the first air chamber 11, after entering the first air chamber 11 through the air inlet conduit 112, the oxygen will naturally go forward to the second air chamber 12 located above, and then go backward to the second air chamber 12 located below after colliding with the wall surface of the second air chamber 12, so that the oxygen will fill the whole first air chamber 11 and the second air chamber 12, at this time, the water condensed in the oxygen gas pipe 2 by the water in the oxygen gas will be discharged into the first air chamber portion through the circulating pipe 111, and the other part of the water in the oxygen gas will be condensed into water drops in the first air chamber portion 11 and the second air chamber portion 12, and the oxygen gas remained at the bottom of the first air chamber 11 and the oxygen gas without the excess water is output through the air outlet pipe 122, the connecting pipe 121 and the oxygen gas pipe 3 of the second air chamber 12, so that the oxygen gas achieves the purpose of removing the excess water.

The conventional water collector 1 seems to achieve the purpose of removing the excessive water in the oxygen; however, after the assembly, the horizontal heights of the pipe orifice of the gas inlet pipe 112 of the first gas chamber 11 and the pipe orifice of the gas outlet pipe 122 of the second gas chamber 12 in the water collector 1 are relatively close to each other, or the combination of the first gas chamber 11 and the second gas chamber 12 is wrong, so that the pipe orifice of the gas outlet pipe 122 and the pipe orifice of the gas inlet pipe 112 are in a straight line, and after oxygen enters the first gas chamber 11 through the gas inlet pipe 112, a relatively high proportion of oxygen directly enters the gas outlet pipe 122 of the second gas chamber 12 and is directly output to the outside, and this phenomenon will greatly reduce the chance of water condensation in the oxygen, so that the water collector 1 cannot exert the proper water collection effect, and finally, the adverse phenomenon that the water content of the oxygen output by the water collector 1 is still high is relatively unfavorable for the subsequent application.

Disclosure of Invention

The present invention relates to a water collector, which mainly overcomes the problem of insufficient water removal operation when the water collector removes the excessive water carried in the oxygen output from the oxygen generator.

To achieve the above object, the present invention provides a water collector. The water collector at least comprises a first air chamber part and a second air chamber part, wherein the bottom of the first air chamber part is externally provided with a connecting pipe, the first air chamber part is internally provided with an air inlet guide pipe, and the inner diameters of the connecting pipe and the air inlet guide pipe are communicated; in addition, the top of the second air chamber part is externally provided with a connecting pipe, the second air chamber part is internally provided with an air outlet guide pipe, the pipe inner diameters of the connecting pipe and the air outlet guide pipe are communicated, the front end of the air outlet guide pipe is provided with a front end part with larger inner pipe diameter, and the pipe orifice of the front end part exceeds the lower end edge of the second air chamber part.

The application effect of the invention is that after the first air chamber part and the second air chamber part are assembled and combined, the first air chamber portion can receive oxygen, after the oxygen enters the first air chamber portion through the air inlet conduit, the level of the front end pipe orifice of the air outlet conduit in the second air chamber part is far lower than that of the air inlet conduit, so that the front end pipe orifice is far away from the pipe orifice of the air inlet conduit, and can avoid the combination error between the first air chamber and the second air chamber, so that the outlet duct of the first air chamber is aligned with the inlet duct of the second air chamber, so that the oxygen output from the inlet conduit will not flow into the outlet conduit directly and output outwards, so as to increase the retention time of the oxygen in the first and second air chambers, thereby facilitating the condensation of the water in the oxygen to effectively remove most of the water in the oxygen.

Drawings

FIG. 1 is a schematic view of a conventional water collector.

Fig. 2 is a schematic view of an embodiment of a conventional sump.

Fig. 3 is an exploded view of the present invention.

FIG. 4 is an assembled cross-sectional view of the present invention.

Fig. 5 is an embodiment of the present invention.

FIGS. 6-8 are schematic diagrams of the assembly operation of the present invention.

FIG. 9 is a schematic view of another embodiment of the present invention.

Description of the figure numbers:

in the prior art

1 Water collector 11 first air chamber part

111 connecting pipe 112 air inlet conduit

12 second air chamber part

121 connecting pipe 122 air outlet conduit

2 oxygen gas delivery pipe

3 oxygen gas conveying pipe

The invention

4 water collector 41 first air chamber part

411 connecting pipe 412 air inlet conduit

413 neck 414 concave ring groove

415 step 416 Ring wall

417 channel 418 caulking groove

419 symbol

42 second air chamber portion

421 connecting pipe 422 air outlet conduit

423 front end 424 torus

425 annular ring 426 protrusions

427 designation

5 sealing ferrule

6 oxygen conveying pipe

7 oxygen conveying pipe.

Detailed Description

For the expert to further understand the objects, technical means applied and the effects produced by the application of the present invention, please refer to the following description with reference to the drawings.

Referring to fig. 3 and 4, the water collector 4 of the present invention at least comprises a first air chamber 41 and a second air chamber 42, wherein the first air chamber 41 and the second air chamber 42 are both hollow cylinders with one closed end and one open end.

Wherein the bottom of the first air chamber 41 is externally provided with a connection tube 411, the first air chamber 41 is internally provided with an air inlet conduit 412, the inner diameters of the connecting pipe 411 and the air inlet conduit 412 are communicated with each other, and furthermore, the upper outer edge of the first air chamber 41 forms a neck portion 413 with a smaller outer diameter, the bottom of the neck portion 413 has a concave ring groove 414, a sealing ring 5 is sleeved in the concave ring groove 414, the connection between the groove 414 and the cylinder body of the first chamber portion 41 forms a step portion 415, the step 415 and the cylinder of the first chamber 41 form a ring wall 416, the outer surface of the neck 413 has two channels 417 formed along the axial direction of the first chamber 41, the channel 417 extends from the upper end of the neck 413 and terminates in the neck 413, the slot 417 terminates to form a slot 418 along the radial direction of the neck 413, and the barrel of the first air chamber portion 41 has an indication 419 at a position corresponding to one of the slots 418.

The second air chamber 42 has a connecting tube 421 outside the top, an air outlet conduit 422 inside the second air chamber 42, the connecting tube 421 and the air outlet conduit 422 are connected to each other, and the front end of the air outlet conduit 422 has a front end portion 423 with a larger inner diameter, the front end portion 423 has a nozzle extending beyond the lower end edge of the second air chamber 42, the inside of the front end portion 423 is connected to the air outlet conduit 422 and forms an annular surface 424, in practice, the front end portion 423 and the air conduit 422 can be separated and can be combined into a whole or integrated into a whole, furthermore, the lower end edge of the second air chamber 42 forms a ring portion 425 with a larger inner diameter, the inner wall surface of the second air chamber 42 is connected to the ring portion 425 and forms at least two raised protrusions 426, and the cylindrical body of the second air chamber 42 itself has a marker 427 corresponding to the position of one of the protrusions 426.

Referring to fig. 4 and 5, in the implementation of the present invention, the connection pipe 411 of the first chamber portion 41 is first connected to the oxygen delivery pipe 6 of the oxygen generation device, but the oxygen generation device is not a main requirement of the present patent, and therefore, it is not described in detail herein; when the connection pipe 411 of the first air chamber 41 is connected to the oxygen delivery pipe 6 of the oxygen generator, the oxygen supplied from the oxygen delivery pipe 6 can be received naturally; in addition, a connection tube 421 at the top of the second air chamber 42 is connected to another oxygen delivery tube 7, and the oxygen delivery tube 7 extends to the application site such as human body or other equipment.

The ring portion 425 of the second chamber portion 42 is fitted over the neck portion 413 of the first chamber portion 41, and the protrusion 426 of the second chamber portion 42 is guided into the groove 416 of the first chamber portion 41 as shown in fig. 6 ~ 8, wherein when the protrusion 426 extends to the end of the groove 416, the end of the second chamber portion 42 covers the step portion 415 of the first chamber portion 41 and is disposed on the ring wall 417, and the sealing ring 5 disposed in the groove 414 of the first chamber portion 41 enables the first chamber portion 41 and the second chamber portion 42 to be connected to each other to achieve an airtight effect, and then the second chamber portion 42 is rotated to enable the second chamber portion 42 to be screwed into the fixed chamber portion 417 to be connected to the second chamber portion 418, and the second chamber portion 42 is connected to the second chamber portion 418 and the second chamber portion 42 to be connected to the second chamber portion 418.

Referring to fig. 5, after the first air chamber 41 and the second air chamber 42 are assembled, the first air chamber 41 and the second air chamber 42 are isolated from the outside and the inside is communicated with each other, then the first air chamber 41 can receive the oxygen from the oxygen delivery pipe 6, and after the oxygen circulation pipe 411 and the air inlet pipe 412 of the oxygen delivery pipe 6 enter the first air chamber 41, the oxygen will continue to the top of the second air chamber 42 and then be collided and turned back, and finally fill the first air chamber 41 and the second air chamber 42, the oxygen will collide with the inner wall surfaces of the first air chamber 41 and the second air chamber 42 to condense the entrained water, finally condense the majority of the water in the oxygen into water drops and flow into the bottom of the first air chamber 41, so as to achieve the operation of removing the majority of the water in the oxygen, and then the oxygen with the removed majority of the water will follow the air outlet pipe 422 of the second air chamber 42, The connection pipe 421 is externally output through the oxygen delivery pipe 7 for supply.

Wherein, the front end 423 of the outlet pipe 422 of the present invention protrudes out of the lower end edge of the second air chamber 42 and enters into the first air chamber 41, so that the horizontal height of the pipe orifice of the front end 423 is far lower than the horizontal height of the inlet pipe 412, and the pipe orifice of the front end 423 is far away from the pipe orifice of the inlet pipe 412, so that the condensed water and oxygen output from the inlet pipe 412 will not directly flow into the outlet pipe 422 and output directly to the outside, thereby avoiding outputting oxygen with too high water content, and simultaneously, the oxygen can increase the remaining time in the first air chamber 41 and the second air chamber 42, thereby facilitating the condensation operation of water in the oxygen; furthermore, as shown in fig. 9, the front end of the outlet conduit 422 of the second air chamber 42 is a front end portion 423 with a larger inner diameter, the front end portion 423 with a larger inner diameter can help to guide the oxygen into the outlet conduit 422, and the front end portion 423 with a larger inner diameter increases the surface area effect of the collision with the oxygen, which can help to condense the moisture in the oxygen, and the design of the ring surface 424 in the front end portion 423 also helps to make the oxygen collide with the ring surface to generate the moisture condensing effect, and the condensed moisture naturally flows downward from the inside of the front end portion 423 to the bottom of the first air chamber 41 to be accumulated. When the water in the bottom of the first air chamber 41 is accumulated to a certain amount, the first air chamber 41 and the second air chamber 42 are separated and the water is poured out, and then the first air chamber 41 and the second air chamber 42 are assembled again for further use.

The present invention is applied to the above structure, wherein the front end 423 of the outlet conduit 422 of the second air chamber 42 has a larger inner diameter, and the outlet conduit 422 (including the front end 423) of the second air chamber 42 and the inlet conduit 412 of the first air chamber 41 are in a staggered position, so that the level of the orifice of the front end 423 is far lower than the level of the inlet conduit 412, so that the condensed water and oxygen output from the inlet conduit 412 do not directly flow into the outlet conduit 422 and directly output to the outside, and the oxygen can increase the retention time in the first air chamber 41 and the second air chamber 42, and the front end 423 with a larger inner diameter can increase the surface area colliding with the oxygen, thereby facilitating the condensation of the water in the oxygen.