CN113828124A

CN113828124A - Gas-water separator assembly

Info

Publication number: CN113828124A
Application number: CN202111282229.5A
Authority: CN
Inventors: 蒋昭斌; 黄业浩
Original assignee: Foshan Yifa Intelligent Technology Co ltd
Current assignee: Foshan Yifa Intelligent Technology Co ltd
Priority date: 2021-11-01
Filing date: 2021-11-01
Publication date: 2021-12-24

Abstract

The invention discloses a gas-water separator assembly, which comprises a box body and a front cover, wherein the bottom end of the box body is provided with a water inlet, a water outlet and a gas inlet, the front cover is matched with the top end of the box body, a gas flow buffer cavity is arranged between the front cover and the inner wall of the box body, a guide groove is arranged between the front cover and the box body and is communicated with the gas flow buffer cavity, and a gas outlet is arranged on the guide groove. The bottom end of the box body is provided with the air inlet, so that the prepared hydrogen and oxygen enter the box body through the air inlet, and water and steam are primarily separated through the water in the box body; through the air current cushion chamber for the oxyhydrogen gas that produces cushions, in a large amount of beads fall back to the box body through the cushioning effect of air current cushion chamber, gaseous entering into the guide slot after, gaseous flowing out via the gas outlet, and a small amount of beads flow back to the box body via the guide slot, make the oxyhydrogen gas that flows out via the gas outlet directly inhaled by the human body, need not external vapor-liquid separation structure, convenient to use does benefit to and reduces overall cost, and has guaranteed the security of using.

Description

Gas-water separator assembly

Technical Field

The invention belongs to a gas-water separation device, and particularly relates to a gas-water separator assembly.

Background

When the existing oxyhydrogen machine is used, the prepared hydrogen and oxygen are discharged through the air outlet hole, and a user breathes the hydrogen and the oxygen, and the gas can carry more water drops when being discharged, so that the hydrogen and the oxygen are inconvenient to directly inhale through a respirator. In order to reduce the direct suction of water drops, a water-gas separation bag is connected at the joint of the gas outlet of the oxyhydrogen machine and the respirator, so that when oxyhydrogen passes through the water-gas separation bag, the water drops fall into the water-gas separation bag due to the dead weight, gas normally flows, and water-gas separation is realized. When the oxyhydrogen machine is used, an external water-gas separation structure is needed, the oxyhydrogen machine is inconvenient to wear, the use is influenced, and the wide popularization is not facilitated; and the water-gas separation structure needs to be replaced frequently, so that the use cost is increased. Meanwhile, when the hydrogen and the oxygen are mixed to reach a certain mixing ratio, explosion is easy to occur when the hydrogen and the oxygen are ignited, so that the hydrogen content of the oxyhydrogen machine needs to be strictly controlled when the oxyhydrogen machine is used.

Disclosure of Invention

The present invention has an object to provide a gas-water separator assembly capable of solving at least one of the above problems.

According to one aspect of the invention, the gas-water separator combination comprises a box body and a front cover, wherein a water inlet, a water outlet and an air inlet are formed in the bottom end of the box body, the front cover is matched with the top end of the box body, an airflow buffer cavity is formed between the front cover and the inner wall of the box body, a guide groove is formed between the front cover and the box body and communicated with the airflow buffer cavity, and an air outlet is formed in the guide groove.

The invention has the beneficial effects that: the bottom end of the box body is provided with the air inlet, so that the prepared hydrogen and oxygen enter the box body through the air inlet, and water and steam are primarily separated through the water in the box body; through being equipped with the air current cushion chamber for the oxyhydrogen gas that produces cushions, and a large amount of beads fall back to the box body through the cushioning effect of air current cushion chamber in, gaseous entering into the guide slot after, gaseous flowing out via the gas outlet, and a small amount of beads flow back to the box body via the guide slot, make the oxyhydrogen gas that flows out via the gas outlet directly inhale by the human body, need not external water gas separation structure, convenient to use has reduced external structure's wasting of resources, does benefit to and reduces overall cost. Meanwhile, the gas flow buffer cavity is arranged, so that the gas flow buffer space is reduced, the volume of gas is reduced, the gas from the gas outlet reaches the safe range of the combustion and explosion energy value, the explosion after the generated hydrogen and oxygen are mixed is effectively avoided, and the use safety is ensured.

In some embodiments, the box body comprises an upper plate, the upper plate is arranged at the top end of one side wall of the box body, and one side of the front cover is attached to the upper plate. Therefore, the box body can be conveniently matched with the front cover by arranging the upper plate.

In some embodiments, the front cover is provided with a front side surface, a rear side surface and a bottom surface, the rear side surface is attached to the upper plate, the front side surface is positioned in front of the rear side surface, the bottom surface is an inclined surface, the bottom surface is positioned below the rear side surface, and a cavity formed among the bottom surface, the front side surface and the upper plate is an airflow buffer cavity. From this, through being equipped with the bottom surface of slope, can make things convenient for gas to upwards enter into the guide slot along the inclined plane, the drop of water has realized the aqueous vapor separation along the downward flow box body of inclined plane simultaneously.

In some embodiments, one side of the top end of the bottom surface is provided with an air guide cavity, the air guide cavity is positioned behind the front side surface, one end of the air guide cavity is communicated with the airflow buffer cavity, and the other end of the air guide cavity is communicated with the guide groove. Therefore, the air in the air flow buffer cavity enters the guide groove through the air guide cavity, water drops are greatly prevented from entering the guide groove through the air guide cavity, and the air entering the guide groove basically realizes water-air separation.

In some embodiments, the guide groove comprises an air guide groove and a first water guide groove, the air guide groove is horizontally arranged, the first water guide groove is communicated with one end of the air guide groove and is vertically arranged, the air guide cavity is communicated with the other end of the air guide groove, and the air outlet is positioned at the joint of the air guide groove and the first water guide groove. From this, through being equipped with vertical first guiding gutter for the gas that contains minute quantity of drop flows back to in the box body through first guiding gutter behind the guiding gutter, and gaseous via the gas outlet discharge, has effectively prevented the drop of water along with gas outgoing, has realized the aqueous vapor separation.

In some embodiments, a second water chute is arranged on the rear side surface of the front cover, the top end of the second water chute is communicated with the air guide groove, and the bottom end of the second water chute is communicated with the air flow buffer cavity. Therefore, the second water guide groove is arranged, so that when gas passes through the gas guide groove, water drops flow back to the box body through the second water guide groove, and the water drops are prevented from being discharged along with the gas.

In some embodiments, the second water chute is obliquely arranged, the top end of the second water chute is provided with a water collecting cavity, the top end of the second water chute is communicated with the middle part of the first water chute, and the bottom end of the second water chute is arranged opposite to the bottom end of the first water chute. Therefore, by arranging the water accumulation cavity, when gas flows through the gas guide groove, water vapor enters a larger space of the water accumulation cavity, water drops are deposited under the action of the water accumulation cavity and flow back to the box body along the second water guide groove, and the gas continuously flows along the gas guide groove to the gas outlet to be discharged; because the bottom of second guiding gutter sets up with the bottom of first guiding gutter relatively, be convenient for all be located the minimum water level below in the box body with the bottom of first guiding gutter and second guiding gutter, the rivers backward flow in two guiding gutters of being convenient for has avoided the air current that the bubble blasting formed in the box body simultaneously, enters into the gas outlet by two guiding gutters, has effectively prevented that moisture from discharging by the gas outlet.

In some embodiments, the gas-water separator assembly further comprises a first water level sensor and a second water level sensor, the first water level sensor and the second water level sensor are respectively arranged at two sides of the box body, and the first water level sensor and the second water level sensor respectively correspond to the bottom end and the top end of the airflow buffer cavity. From this, be equipped with first level sensor and second level sensor and can monitor the water level in the box body, prevent that the water level in the box body from crossing low to and prevent that the water in the box body from spilling over, guaranteed holistic normal use.

In some embodiments, the bottom of the box body is provided with a gas-water box bottom cover and a gas inlet bottom cover, the water outlet and the water inlet are both arranged on the gas-water box bottom cover, the gas inlet bottom cover is matched with the gas-water box bottom cover, a filter screen is arranged at the matching position of the gas-water box bottom cover and the gas inlet bottom cover, and the gas inlet is arranged on the gas inlet bottom cover. Therefore, the filter screen is arranged, so that large bubbles can be prevented from being generated when gas enters the box body, the bubbles are refined, noise is reduced, and meanwhile, small bubbles can be formed in the box body, so that more water in the gas is retained in the box body; meanwhile, the concentrated impact force of the air on the airflow buffer cavity can be reduced by small bubbles formed after passing through the filter screen, and the moisture entering the guide groove is reduced; meanwhile, the refined bubbles avoid the direct communication between the electrolytic bath and the air outlet; therefore, the direct burning explosion of the gas generated in the electrolytic cell when the gas outlet communicated with the outside is burnt and exploded is avoided, and the safety is ensured.

In some embodiments, the upper plate is provided with an air guide port and a terminal air outlet, the terminal air outlet and the air guide port are communicated and are respectively positioned at two opposite sides of the upper plate, the air guide port is communicated with the air outlet, and a pressure detector is arranged at the position where the air guide port is communicated with the air outlet. From this, through being equipped with pressure detector, can conveniently detect the atmospheric pressure of gas outlet department, when atmospheric pressure was too high, stopped corresponding equipment, guaranteed the security of using.

Drawings

FIG. 1 is a schematic structural diagram of a gas-water separator assembly according to the present invention;

FIG. 2 is a schematic view of another aspect of the gas-water separator assembly of the present invention;

FIG. 3 is a schematic view of an exploded structure of a gas-water separator assembly according to the present invention;

FIG. 4 is a schematic structural diagram of a front cover of a gas-water separator assembly according to the present invention;

FIG. 5 is a schematic structural diagram of an upper plate of a gas-water separator assembly according to the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1 to 5: the utility model provides a gas-water separator combination, includes box body 1 and protecgulum 2, and the bottom of box body 1 is equipped with water inlet 11, delivery port 12 and air inlet 13, and protecgulum 2 cooperatees with the top of box body 1, is equipped with air current cushion chamber 3 between protecgulum 2 and the 1 inner wall of box body, is equipped with guide slot 4 between protecgulum 2 and the box body 1, and guide slot 4 communicates with air current cushion chamber 3, is equipped with gas outlet 5 on the guide slot 4. In the use, can add water to the box body 1 through water inlet 11, can discharge the water in the box body 1 through being equipped with delivery port 12 for the water level in the box body 1 remains on required water level all the time. When the box body 1 needs to be cleaned, water in the box body 1 can be completely discharged through the water outlet 12, and cleaning is facilitated.

The box body 1 comprises an upper plate 14, the upper plate 14 is arranged at the top end of one side wall of the box body 1, and one side of the front cover 2 is attached to the upper plate 14. The upper plate 14 can be fixed on the top of the side wall at the rear side of the box body 1 in an adhering way, and the top of the upper plate 14 is higher than the top of the front side of the box body 1, so that the installation of each structure on the upper plate 14 is convenient.

In order to facilitate the installation and matching of the front cover 2 and the box body 1, the left side and the right side of the box body 1 are obliquely arranged, and the front cover 2 is tightly matched with the box body 1. The top end of the side wall of the front side of the box body 1 is provided with a mounting step 17, the bottom end of the front cover 2 is provided with a convex block 25, and the convex block 25 is matched and fixed with the mounting step 17; the left and right side walls of the box body 1 are attached to the left and right side walls of the front cover 2, so that the water and air leakage of the box body 1 is effectively prevented.

The front cover 2 is provided with a front side surface 21, a rear side surface 22 and a bottom surface 23, the rear side surface 22 is attached to the upper plate 14, the front side surface 21 is positioned in front of the rear side surface 22, the bottom surface 23 is an inclined surface, the bottom surface 23 is positioned below the rear side surface 22, and a cavity formed among the bottom surface 23, the front side surface 21 and the upper plate 14 is an airflow buffer cavity 3. Wherein the top ends of the front side surface 21 and the back side surface 22 coincide.

One side of the top end of the bottom surface 23 is provided with an air guide cavity 6, the air guide cavity 6 is positioned behind the front side surface 21, one end of the air guide cavity 6 is communicated with the airflow buffer cavity 3, and the other end of the air guide cavity is communicated with the guide groove 4. The air guide cavity 6 is composed of one side of the bottom surface 23, the back surface of the front side surface 21 and the side wall of the box body 1, so that air enters the air guide cavity 6 and then enters the guide groove 4 after passing through the airflow buffer cavity 3.

In the using process, hydrogen and oxygen generated by the oxyhydrogen generator enter the box body 1 through the air inlet 13 at the bottom of the box body 1, water and air are primarily separated through water in the box body 1, then bubbles rise and then break, the gas is released, and water drops flow back through the side wall of the airflow buffer cavity 3; the air enters the air guide cavity 6 at one side of the air flow buffer cavity 3, and the air guide cavity 6 is of a narrow slit structure, so that the air flowing through the air guide cavity 6 after passing through the air flow buffer cavity 3 only has a very small amount of water; then after passing through the guide slot 4, the oxyhydrogen that flows out through the gas outlet 5 can be directly inhaled by the user, convenient operation need not external water vapor separation structure.

The guide groove 4 comprises an air guide groove 41 and a first water guide groove 42, the air guide groove 41 is horizontally arranged, the first water guide groove 42 is communicated with one end of the air guide groove 41 and is vertically arranged, the air guide cavity 6 is communicated with the other end of the air guide groove 41, and the air outlet 5 is positioned at the joint of the air guide groove 41 and the first water guide groove 42. The gas enters the gas guide groove 41 after passing through the gas guide cavity 6, the gas is directly discharged from the gas outlet 5 after passing through the gas guide groove 41, and a small amount of residual water drops flow back to the box body 1 along the first water guide groove 42.

The rear side surface of the front cover 2 is provided with a second water chute 24, the top end of the second water chute 24 is communicated with the air guide groove 41, and the bottom end is communicated with the air flow buffer cavity 3. By providing the second water guiding groove 24, water drops deposited when the gas flows through the gas guiding groove 41 can also flow into the box body 1 along the second water guiding groove 24, so as to separate water from gas for multiple times.

The second water chute 24 is obliquely arranged, the top end of the second water chute 24 is provided with a water accumulation cavity 25, the top end of the second water chute 24 is communicated with the middle part of the first water chute 42, and the bottom end of the second water chute 24 is opposite to the bottom end of the first water chute 42. The water accumulation cavity 25 is a conical hole, the aperture of one side close to the end face of the rear side is larger, and the aperture of the other side is smaller; therefore, when the gas passes through the gas guide groove 41 and flows to the water accumulation cavity 25, the water vapor in the gas acts on the side wall of the water accumulation cavity 25, so that water drops are deposited in the water accumulation cavity 25, the deposited water flows back to the box body 1 through the second water guide groove 24, and the gas is discharged from the gas outlet after passing through the gas guide groove 41. The water deposited in the air guide groove 41 flows back to the box body through the first water guide groove, and water-gas separation is realized.

The gas-water separator assembly further comprises a first water level sensor 7 and a second water level sensor 8, wherein the first water level sensor 7 and the second water level sensor 8 are respectively arranged on two sides of the box body 1, and the first water level sensor 7 and the second water level sensor 8 respectively correspond to the bottom end and the top end of the airflow buffer cavity 3. Through first level sensor 7, can detect the minimum water level in the box body 1 for the water level in the box body 1 keeps the bottom position at air current cushion chamber 3, and when the water level was less than this position, the water of external water tank got into box body 1 in via the water inlet, in time supplyed. From this, can make the water in the box body 1 keep at higher water level, the bubble that gas formed through the water in the box body when the blasting, the drop of water can be used in the lateral wall of air current cushion chamber 3, realizes the aqueous vapor separation. Through being equipped with second level sensor 7 to be located the top of air current cushion chamber 3, make the water level can not submerge whole air current cushion chamber 3, guaranteed that gas can have the space to flow out.

In the in-service use process, the water level in the box body 1 is located the upper and lower both ends of the bottom surface 23 of slope, and guarantees that the bottom of first guiding gutter 42 and second guiding gutter 24 can be located below the water level of box body 1, prevents that the drop of water in the box body 1 from entering into the gas outlet via two guiding gutters, from this, has avoided the drop of water to flow to the gas outlet via the guiding gutter, and the drop of water that has significantly reduced flows. Meanwhile, the water level in the box body 1 is kept at a higher position, so that the gas volume of oxyhydrogen in the airflow buffer cavity 3 is kept within the range of 3-5 ml, the flow of final flowing hydrogen and oxygen is ensured to be smaller, explosion can not occur during ignition, and the use safety is ensured.

The bottom of the box body 1 is provided with a gas-water box bottom cover 15 and a gas inlet bottom cover 16, the water outlet 12 and the water inlet 11 are both arranged on the gas-water box bottom cover 15, the gas inlet bottom cover 16 is matched with the gas-water box bottom cover 15, a filter screen 9 is arranged at the matching position of the gas inlet bottom cover and the gas inlet bottom cover, and the gas inlet 13 is arranged on the gas inlet bottom cover 16. Wherein, the gas water box bottom cover 15 is covered with the bottom of the box body 1, which is convenient for the opening of the water inlet 11 and the water outlet 12; the air inlet bottom cover 16 is fixed with the gas-water box bottom cover 15, and the gas-water box bottom cover 15 is provided with a communicating hole for facilitating the communication of the air inlet 13 and the box body. The filter screen 9 is a micron-sized filter screen, hydrogen and oxygen produced by the oxyhydrogen generator enter through the air inlet 13, and bubbles can be refined through the filter screen 9, so that the noise of bubbles during rising in the box body 1 is greatly reduced, and the noise of bubble blasting can also be reduced.

The upper plate 14 is provided with an air guide opening 10 and a terminal air outlet 20, the terminal air outlet 20 is communicated with the air guide opening 10 and is respectively positioned at two opposite sides of the upper plate 14, the air guide opening 10 is communicated with the air outlet 5, and a pressure detector is arranged at the communication position of the air guide opening 10 and the air outlet 5. Wherein, the air guide port 10 is communicated with the air outlet 5 through an air pipe. The pressure detector is arranged, so that the air pressure at the air port 5 can be detected, when the gas cannot be normally discharged, the pressure at the air port 5 is increased, the oxyhydrogen generator can be stopped, the continuous generation of oxyhydrogen is stopped, and the use safety is ensured.

In the in-service use in-process, for the convenience box body 1 is fixed in the installation on oxyhydrogen machine, in the outside of the 1 left and right sides of box body, all the installation is fixed with fixed plate 30, can with the oxyhydrogen machine in corresponding slotted hole card go into the cooperation through fixed plate 30, simple to operate.

The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, many variations and modifications can be made without departing from the inventive concept of the present invention, which falls into the protection scope of the present invention.

Claims

1. The utility model provides a gas-water separator combination, its characterized in that, includes box body (1) and protecgulum (2), the bottom of box body (1) is equipped with water inlet (11), delivery port (12) and air inlet (13), protecgulum (2) cooperate with the top of box body (1), be equipped with air current cushion chamber (3) between protecgulum (2) and box body (1) inner wall, be equipped with between protecgulum (2) and box body (1) guide slot (4), guide slot (4) and air current cushion chamber (3) intercommunication, be equipped with gas outlet (5) on guide slot (4).

2. The gas-water separator assembly according to claim 1, wherein the box body (1) comprises an upper plate (14), the upper plate (14) is arranged at the top end of one side wall of the box body (1), and one side of the front cover (2) is attached to the upper plate (14).

3. The gas-water separator assembly according to claim 2, wherein the front cover (2) is provided with a front side surface (21), a rear side surface (22) and a bottom surface (23), the rear side surface (22) is attached to the upper plate (14), the front side surface (21) is located in front of the rear side surface (22), the bottom surface (23) is an inclined surface, the bottom surface (23) is located below the rear side surface (22), and a cavity formed among the bottom surface (23), the front side surface (21) and the upper plate (14) is an airflow buffer cavity (3).

4. A gas-water separator combination according to claim 3, wherein one side of the top end of the bottom surface (23) is provided with a gas guide cavity (6), the gas guide cavity (6) is positioned behind the front side surface (21), one end of the gas guide cavity (6) is communicated with the gas flow buffer cavity (3), and the other end is communicated with the guide groove (4).

5. The gas-water separator assembly according to claim 4, wherein the guide groove (4) comprises an air guide groove (41) and a first water guide groove (42), the air guide groove (41) is horizontally arranged, the first water guide groove (42) is communicated with one end of the air guide groove (41) and vertically arranged, the air guide cavity (6) is communicated with the other end of the air guide groove (41), and the air outlet (5) is located at the joint of the air guide groove (41) and the first water guide groove (42).

6. The gas-water separator assembly according to claim 5, wherein a second water chute (24) is arranged on the rear side surface of the front cover (2), the top end of the second water chute (24) is communicated with the gas chute (41), and the bottom end of the second water chute is communicated with the airflow buffer cavity (3).

7. The gas-water separator assembly according to claim 6, wherein the second water chute (24) is obliquely arranged, the top end of the second water chute (24) is provided with a water collecting cavity (25), the top end of the second water chute (24) is communicated with the middle part of the first water chute (42), and the bottom end of the second water chute (24) is arranged opposite to the bottom end of the first water chute (42).

8. The gas-water separator combination according to any one of claims 1-7, further comprising a first water level sensor (7) and a second water level sensor (8), wherein the first water level sensor (7) and the second water level sensor (8) are respectively disposed at two sides of the box body (1), and the first water level sensor (7) and the second water level sensor (8) respectively correspond to the bottom end and the top end of the airflow buffer chamber (3).

9. The gas-water separator combination according to claim 8, wherein the bottom of the box body (1) is provided with a gas-water box bottom cover (15) and an air inlet bottom cover (16), the water outlet (12) and the water inlet (11) are both arranged on the gas-water box bottom cover (15), the air inlet bottom cover (16) is matched with the gas-water box bottom cover (15), a filter screen (9) is arranged at the matching position of the gas-water box bottom cover and the air inlet bottom cover (16), and the air inlet (13) is arranged on the air inlet bottom cover (16).

10. The gas-water separator assembly according to claim 2, wherein the upper plate (14) is provided with a gas guide port (10) and a terminal gas outlet (20), the terminal gas outlet (20) is communicated with the gas guide port (10) and is respectively located at two opposite sides of the upper plate (14), the gas guide port (10) is communicated with the gas outlet (5), and a pressure detector is arranged at the communication position of the gas guide port (10) and the gas outlet (5).