CN219942107U - Water-steam separation component and heater - Google Patents

Abstract

The utility model discloses a water-vapor separation component and a heater, which comprise a separation box, wherein a water cavity is arranged in the separation box, and the top end of the separation box is provided with a water inlet; the bottom end of the separation box is provided with a first water outlet channel; the top end of the first water outlet channel is communicated with the bottom end of the water cavity; a drainage channel and an exhaust channel are arranged in the water cavity, and one end of the drainage channel is communicated with the water inlet; the drainage channel extends from top to bottom in a nonlinear state in the water cavity so as to guide fluid to be guided out to the first water outlet channel from top to bottom in the nonlinear state; the top inlet of the exhaust channel is higher than the top inlet of the first water outlet channel and extends to the top of the water cavity. A heater comprising the water vapor separator assembly. According to the utility model, the drainage channel can be arranged in the separation box, the drainage channel can guide the fluid to be led out in a nonlinear state, the overflow area and time of the fluid in the separation box are prolonged, and the water-vapor separation effect is improved.

Description

Water-steam separation component and heater

Technical Field

The utility model relates to the technical field of household appliances, in particular to a water-vapor separation component and a heater.

Background

At present, in heating products, especially instant heating products, a great amount of steam is generated if the boiling water directly exits from a water outlet of a machine due to high temperature, so that the risk of scalding users is caused.

The boiling point is increased due to the additional pressurization of the heating cavity, and a large amount of steam can be discharged at the moment when the heater discharges water; particularly in high altitude areas, the boiling point of water is low, but the water in the heater can still be heated to 100 ℃, and when the water is discharged from the heater, the water is gasified instantly, so that a large amount of steam and noise are generated.

Disclosure of Invention

In order to overcome the defects of the prior art, one of the purposes of the utility model is to provide a water-steam separation component, which can be provided with a drainage channel in a separation box, wherein the drainage channel can guide fluid to be led out in a nonlinear state, so that the flow area and time of the fluid in the separation box are prolonged, and the water-steam separation effect is improved.

The second purpose of the utility model is to provide a heater, which is provided with a water-vapor separation component and can improve the water-vapor separation effect.

One of the purposes of the utility model is realized by adopting the following technical scheme:

the water-vapor separation component comprises a separation box, wherein a water cavity is arranged in the separation box, and a water inlet is formed in the top end of the separation box; the bottom end of the separation box is provided with a first water outlet channel; the top end of the first water outlet channel is communicated with the bottom end of the water cavity; a drainage channel and an exhaust channel are arranged in the water cavity, and one end of the drainage channel is communicated with the water inlet; the drainage channel extends from top to bottom in a nonlinear state in the water cavity so as to guide fluid to be guided out to the first water outlet channel from top to bottom in a nonlinear state; the top end inlet of the exhaust channel is higher than the top end inlet of the first water outlet channel and extends to the top end of the water cavity; the bottom outlet of the exhaust passage extends to the bottom end of the separation box.

Further, first spoilers are arranged on the peripheral wall of the top opening of the first water outlet channel at intervals.

Further, the water-vapor separation component further comprises a water outlet nozzle, and the water outlet nozzle is sleeved outside the first water outlet channel; the inner wall of the water outlet nozzle and the outer wall of the first water outlet channel form a water outlet interval at intervals; at least two second water outlet channels are arranged in the water cavity, and the at least two second water outlet channels are symmetrically distributed around the first water outlet channel at intervals; the bottom end of the second water outlet channel is spaced from the water outlet; the top inlet of the second water outlet channel is higher than the top inlet of the first water outlet channel.

Further, the inner wall of the water outlet nozzle is provided with a plurality of positioning ribs, the positioning ribs are circumferentially distributed at intervals around the central axis of the water outlet nozzle, and the positioning ribs are used for abutting against the outer wall of the first water outlet channel; the bottom outlet of the first water outlet channel extends out of the bottom end of the water outlet nozzle.

Further, a plurality of notches are formed in the peripheral wall of the bottom outlet of the first water outlet channel; the notches are circumferentially distributed at intervals around the central axis of the first water outlet channel.

Further, the inner wall of the water outlet nozzle is provided with a plurality of positioning ribs, the positioning ribs are circumferentially distributed at intervals around the central axis of the water outlet nozzle, and the positioning ribs are used for abutting against the outer wall of the first water outlet channel; the bottom end of the first water outlet channel is inwards contracted in the water outlet nozzle; the inner wall of the water outlet nozzle is provided with a drainage surface which gradually inclines towards the first water outlet channel from top to bottom.

Further, second spoilers are arranged on the peripheral wall of the top opening of the second water outlet channel at intervals.

Further, the bottom wall of the drainage channel spirally extends from top to bottom; a drainage plate is arranged in the water cavity, and the side wall of the drainage plate close to the water inlet and the inner wall of the water cavity are spaced to form the drainage channel; the drainage plate extends along the extending direction of the drainage channel.

Further, the top end of the separation box is covered with a cover plate; the cover plate is provided with a drainage groove which is sunken towards the water cavity; the drainage groove is arranged corresponding to the top inlet of the exhaust channel; the inner peripheral wall of the drainage groove is provided with a guide surface which is used for guiding condensed water to avoid the top inlet of the exhaust channel.

Further, a pressure relief opening is formed in the separation box, and the pressure relief opening is formed in the side portion, away from the drainage channel, of the separation box.

The second purpose of the utility model is realized by adopting the following technical scheme:

a heater comprising the water vapor separator assembly.

Compared with the prior art, the utility model has the beneficial effects that:

firstly, the drainage channel extends from top to bottom, an upper flow empty path and a lower flow empty path are increased, secondly, the drainage channel extends in a nonlinear state, even if fluid flows roundabout, the length of the flow path is increased, the flow speed can be reduced, the flow area and the flow time of the fluid in the water-vapor separation box can be increased, and the water-vapor separation effect is improved.

Drawings

FIG. 1 is a schematic diagram of a water vapor separation module of the present utility model;

FIG. 2 is a schematic view of the structure of the separation cartridge of the present utility model;

FIG. 3 is a schematic view of a separator of the present utility model from another perspective;

FIG. 4 is a schematic exploded view of the water vapor separator assembly of the present utility model;

FIG. 5 is a schematic view showing an assembly structure of a water outlet nozzle and a separation box according to the present utility model;

FIG. 6 is a schematic view showing an assembly structure of a water outlet nozzle and a separation box according to another embodiment of the present utility model;

FIG. 7 is a schematic view showing an assembly structure of a water outlet nozzle and a separation box according to another embodiment of the present utility model;

FIG. 8 is a schematic view of a water level structure in a separation cartridge according to the present utility model;

fig. 9 is a schematic view showing another water level structure in the separation cartridge of the present utility model.

In the figure: 10. a separation box; 11. an air inlet; 12. a pressure relief port; 13. a water chamber; 131. a drainage channel; 132. an exhaust passage; 133. a second spoiler; 134. a second water outlet channel; 135. a drainage plate; 14. a first water outlet channel; 141. a first spoiler; 142. a notch; 20. a water outlet nozzle; 21. positioning ribs; 23. a drainage surface; 30. a cover plate; 31. drainage groove.

Detailed Description

The utility model will be further described with reference to the accompanying drawings and detailed description below:

in the description of the present utility model, it should be noted that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, merely to facilitate description of the present utility model and simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

The water-vapor separation component as shown in fig. 1-7 comprises a separation box 10, wherein a water cavity 13 is arranged in the separation box 10, a water inlet is arranged at the top end of the separation box 10, a first water outlet channel 14 is arranged at the bottom end of the separation box 10, the top end of the first water outlet channel 14 is communicated with the bottom end of the water cavity 13, a drainage channel 131 and an exhaust channel 132 can be arranged in the water cavity 13, and one end of the drainage channel 131 is communicated with the water inlet; the drainage channel 131 extends from top to bottom in a non-linear state in the water chamber 13 to guide fluid to be guided out from top to bottom to the first water outlet channel 14 in a non-linear state.

In addition, the top end inlet of the exhaust passage 132 is higher than the top end inlet of the first water outlet passage 14, the exhaust passage 132 may extend to the top end of the water chamber 13, and the bottom end outlet of the exhaust passage 132 penetrates to the outside of the bottom end of the separation box 10 and penetrates to the outside of the separation box 10, and the exhaust passage 132 may exhaust the steam in the water chamber 13.

On the basis of the structure, when the water-vapor separation component is used, the water-vapor separation component can be installed on a hot water device, such as a water heater, a water dispenser, a pipeline machine, a heater and other equipment, when the water-vapor separation component is assembled, the water inlet of the separation box 10 of the water-vapor separation component and the hot water outlet of the hot water device can be assembled, so that heated boiling water can enter the drainage channel 131 of the separation box 10 through the water inlet, be guided to the first water outlet channel 14 through the drainage channel 131 and be guided out through the first water outlet channel 14, and because the boiling water is in a mixed state of water flow and steam, if the boiling water is guided out directly through the first water outlet channel 14, a large amount of steam is generated during the guiding out of the boiling water, and a jet is generated at a water outlet position to scald the situation, and the separation box 10 is arranged, so that the steam can be separated from the water flow when the boiling water guided into the separation box 10 flows in the drainage channel 131, the separated steam can be lifted up and guided into the top end inlet of the exhaust channel 132, and then guided out through the exhaust channel 132, and the water can be directly guided into the first water outlet channel 14 to be guided out, and the jet water outlet channel to be guided out, and the jet water is reduced.

It should be emphasized that, in the present embodiment, the drainage channel 131 extends from top to bottom in the water cavity 13 in a nonlinear state, so that the fluid flowing in the drainage channel 131 may also be guided out from top to bottom to the first water outlet channel 14 in the water cavity 13 in a nonlinear state, firstly, the drainage channel 131 extends from top to bottom, increasing the upper and lower flow empty paths, and secondly, the drainage channel 131 extends in a nonlinear state, that is, even if the fluid flows roundabout, increasing the length of the flow path, and also slowing down the flow velocity, so as to increase the flow area and time of the fluid in the water-vapor separation box 10, and improve the water-vapor separation effect.

In addition, since the top inlet of the exhaust channel 132 extends to the top of the water chamber 13 and the drainage channel 131 guides the water flow from top to bottom, the inlet of the exhaust channel 132 can discharge separated steam, thereby avoiding dripping caused by the water flow guided out from the top inlet of the exhaust channel 132.

Further, first spoilers 141 distributed at intervals may be further disposed on the peripheral wall of the top opening of the first water outlet channel 14, and since the water flow is guided to the top inlet position of the first water outlet channel 14 and is directly collected, a vortex is easily generated at the inlet of the first water outlet channel 14 to affect the discharge of the water flow, and in this embodiment, a plurality of first spoilers 141 are disposed at the top opening position of the first water outlet channel 14, so that the first spoilers 141 can block the buffered water flow, break the flow, reduce the kinetic energy of the water again, and play a role in stabilizing the flow. The problem that the flow state of the outlet water is poor when air is sucked into the water due to the vortex effect is also avoided.

Further, the water-vapor separation component in this embodiment further includes a water outlet nozzle 20, as shown in fig. 4-9, the water outlet nozzle 20 may be sleeved outside the first water outlet channel 14, and the inner wall of the water outlet nozzle 20 and the outer wall of the first water outlet channel 14 form a water outlet space at intervals. In addition, a second water outlet channel 134 is arranged in the water cavity 13, the bottom end of the second water outlet channel 134 is communicated with the water outlet at intervals, and the top end inlet of the second water outlet channel 134 is higher than the top end inlet of the first water outlet channel 14.

In the actual use process of the water heating device, the flow rate of the boiled water is smaller, so that after the boiled water enters the drainage channel 131 through the water inlet, the drainage channel 131 can guide the boiled water to directly enter the first water outlet channel 14 for guiding, namely, only one water outlet level is used for guiding, so that the flow state of the boiled water can be good, and the liquid level (see H1 in fig. 8 and only the liquid level is schematic) of the boiled water is not higher than the top inlet of the second water outlet channel 134 in the guiding process through the inner diameter of the first water outlet channel 14, namely, the boiled water is only guided out from the first water outlet channel 14.

When the normal temperature water or the warm water is discharged, the flow rate is large, and after the fluid is introduced into the drainage channel 131 of the separation box 10, the flow rate of the fluid is large, so that the highest liquid level (see H2 in fig. 9, the liquid level is only shown) exceeds the top end opening of the second water outlet channel 134, and at the same time, the water flows out of the second water outlet channel 134, enters into the water outlet gap formed by the water outlet nozzle 20 and the outer wall of the first water outlet channel 14, and is gathered with the water column of the first water outlet channel 14 to flow out.

It should be noted that, the above-mentioned second water outlet channel can set up two at least, two at least second water outlet channels are around first water outlet channel symmetry interval distribution, so when carrying out warm water or warm water and deriving, can be by two at least second water outlet channels dispersion water conservancy diversion, realize the stationary flow, and rivers follow first water outlet channel's circumference symmetry downwardly flowing to the play water interval to the rivers of first water outlet channel in the bottom and centre assemble, left and right sides symmetry comes down and gathers, can not let the water crooked, flow state control is better.

Specifically, after the water outlet nozzle 20 is sleeved outside the first water outlet channel 14, the water outlet nozzle can be assembled with the bottom end of the separation box 10 by using screws, and a sealing ring is additionally arranged at the joint to prevent water leakage. Or directly adopting ultrasonic sealing welding.

Further, referring to fig. 5, a plurality of positioning ribs 21 may be further disposed on an inner wall of the water outlet nozzle 20, the positioning ribs 21 may be circumferentially spaced around a central axis of the water outlet nozzle 20, and when the water outlet nozzle 20 is sleeved outside the first water outlet channel 14, the positioning ribs 21 may abut against an outer wall of the first water outlet channel 14. Because the water outlet nozzle 20 uses the first water outlet channel 14 as the assembly basis during assembly, the water outlet nozzle 20 is propped against through the positioning ribs 21, the deflection condition of the water outlet nozzle 20 after sleeving can be reduced, namely, the concentricity of the assembled water outlet nozzle can be improved by the plurality of positioning ribs 21 in the circumferential direction, and deflection of diversion water flow is avoided.

Further, referring to fig. 6, the water outlet nozzle may adopt a structure that the outlet at the bottom end of the first water outlet channel 14 extends out of the bottom end of the water outlet nozzle 20, so that the water flow of the outer ring led out at the water outlet interval can be directly led downwards to be concentrated to the water flow of the inner ring led out of the first water outlet channel 14 in the middle, and thus the water flow between the inner ring and the outer ring is easier to be concentrated to the center, so that the water flow state is better.

Further, referring to fig. 6, a plurality of notches 142 are provided on the peripheral wall of the bottom outlet of the first water outlet channel 14, and the notches 142 are circumferentially spaced around the central axis of the first water outlet channel 14, so that a water flow portion led out from the first water outlet channel 14 can be directly led downwards, and a water flow portion led out from the plurality of notches 142 in the circumferential direction can be led out from the outer ring, so that water flow led out from the outer ring at intervals is more easily collected.

Specifically, the two side walls of the notch 142 may be inclined surfaces, which may be inclined from top to bottom inward, so as to more easily guide the water flow to collect.

Further, referring to fig. 7, the water outlet nozzle may have a structure that a plurality of positioning ribs 21 are further disposed on an inner wall of the water outlet nozzle 20, the positioning ribs 21 are circumferentially spaced around a central axis of the water outlet nozzle 20, and when the water outlet nozzle 20 is sleeved outside the first water outlet channel 14, the positioning ribs 21 may abut against an outer wall of the first water outlet channel 14. Because the water outlet nozzle 20 uses the first water outlet channel 14 as the assembly basis during assembly, the water outlet nozzle 20 is propped against through the positioning ribs 21, the deflection condition of the water outlet nozzle 20 after sleeving can be reduced, namely, the concentricity of the assembled water outlet nozzle can be improved by the plurality of positioning ribs 21 in the circumferential direction, and deflection of diversion water flow is avoided.

On the basis of the structure, the bottom end of the first water outlet channel is contracted in the water outlet nozzle 20, the inner wall of the water outlet nozzle is provided with a drainage surface 23 which gradually inclines towards the first water outlet channel from top to bottom, namely, water flow led out from the bottom end of the first water outlet channel is in the water outlet nozzle, and the drainage surface 23 at the bottom end of the water outlet nozzle inclines inwards to realize closing in, so that water flow in a water outlet interval is led to converge towards the water flow in the middle first water outlet channel, and the water flow is easier to converge together.

Similarly, second spoilers 133 may be provided at intervals on the peripheral wall of the top opening of the second water outlet passage 134. The second turbulence plates 133 can break the vortex effect generated by the water flow, break the flow, block the buffer water flow, reduce the kinetic energy of the water again, and play a role in stabilizing the flow. The problem that the flow state of the outlet water is poor when air is sucked into the water due to the vortex effect is also avoided.

Further, the bottom wall of the drainage channel 131 in the present embodiment extends spirally from top to bottom, so that the fluid introduced from the water inlet can flow spirally after entering the drainage channel 131, and the drainage is to extend the path of the water flow through the spiral descending channel, thereby increasing the residence time. Specifically, a drainage plate 135 can be further disposed in the water cavity 13, the side wall of the drainage plate 135 close to the water inlet and the inner wall of the water cavity 13 are spaced to form a drainage channel 131, on the basis of the structure, the drainage plate 135 extends along the extending direction of the drainage channel 131, that is, when the separation box 10 is processed, the drainage plate 135 is directly formed in the separation box 10, the drainage channel 131 can be formed through the separation between the drainage plate 135 and the inner wall of the separation box 10, and the structure such as a groove is not needed to be processed, so that the processing is more convenient.

Of course, the nonlinear state referred to in this embodiment may be the spiral line, the curve, or the bending line.

When the drainage channel 131 extends in a bending line, the drainage plate 135 may be formed by bending a plurality of sections of plates, or may be formed by processing inclined structures that are mutually connected at the bottom wall of the water cavity 13 to form a bending line drainage state, and the drainage plate is specifically selected according to actual needs.

Further, a cover plate 30 may be further covered on the top end of the separation box 10, the cover plate 30 is provided with a drainage groove 31 recessed far from the water cavity 13, the drainage groove 31 is disposed corresponding to the top end inlet of the air exhaust channel 132, and the inner peripheral wall of the specific drainage groove 31 is provided with a guiding surface, so that the guiding surface can guide the condensed water to avoid the top end inlet of the air exhaust channel 132.

It should be noted that, when the heating temperature is high, the amount of generated steam is large, and thus the amount of exhaust gas is relatively large, a large amount of steam is easy to condense on the cover plate 30 of the separation box 10, and a large amount of water droplets generated by condensation fall down, and if the water droplets fall down directly, the water droplets enter the exhaust passage 132, so that water leakage is caused. Therefore, in this embodiment, the drainage groove 31 is disposed at the top opening of the exhaust channel 132, the steam concentrated at the top opening of the exhaust channel 132 is condensed in the drainage groove 31, and the condensed water drops can avoid the top opening of the exhaust channel 132 under the guidance of the drainage surface, so as to guide the water drops to the outside of the exhaust channel 132, so that the water drops cannot drop into the exhaust channel 132, and the occurrence of dripping is reduced.

The drainage surface in the drainage groove 31 in this embodiment may be an umbrella-shaped surface, and the central position of the umbrella-shaped surface corresponds to the top opening position of the exhaust channel 132, and then may drip outward along the umbrella-shaped surface after the water droplets condense, so as to guide the water droplets to avoid the top opening position of the exhaust channel 132. Of course, the inner wall of the drainage groove 31 may be realized by a structure capable of guiding the water flow to the outside, such as an arc surface or an inclined surface, and the like, and the structure may be specifically selected according to actual needs.

Further, a pressure relief opening 12 may be further provided on the separation box 10, and the pressure relief opening 12 is provided on a side portion of the separation box 10 away from the drainage channel, and in the use process of the water heating device, the boiling point of water is generally increased by increasing the pressure of fluid, so that water flow entering the separation box can be prevented from being excessively high in water pressure through the pressure relief opening 12, and a pressure relief valve is provided on the pressure relief opening 12, so as to realize pressure relief.

Specifically, since the pressure relief opening 12 is formed on the side of the separation box 10 away from the drainage channel, when water is guided to the first water outlet channel for guiding out through the drainage channel, the pressure relief valve is opened to relieve pressure, if the pressure relief opening is formed on the same side as the first water outlet channel, water flow state guided out by the first water outlet channel can be influenced by water flow and steam flushed out by the pressure relief opening, so that the pressure relief opening is formed on the side of the separation box away from the first water outlet channel, and water flushed out by the pressure relief opening can not influence the water flow state guided out by the first water outlet channel.

In the case of example 2,

as shown in fig. 1-5, in this embodiment, the water inlet of the separation box 10 of the water-vapor separation component in the above embodiment 1 is connected to the hot water outlet of the hot water device, so that heated boiling water can enter the drainage channel 131 of the separation box 10 through the water inlet, be guided to the first water outlet channel 14 through the drainage channel 131, be guided out through the first water outlet channel 14, and be guided out through the first water outlet channel 14, because the boiling water is in a mixed state of water flow and steam, if the boiling water is guided out directly through the first water outlet channel 14, a large amount of steam is generated during the guiding out of the boiling water, and a jet of air is generated at the water outlet position to scald the boiling water, so that the separation box 10 is arranged, when the boiling water guided into the separation box 10 flows in the drainage channel 131, the steam can be separated from the water flow, the separated steam rises and is guided in through the top inlet of the exhaust channel 132, and then is guided out through the exhaust channel 132, and the water can directly enter the first water outlet channel 14 to be guided out, thereby reducing the jet of the water.

It should be emphasized that, in the present embodiment, the drainage channel 131 extends from top to bottom in the water cavity 13 in a nonlinear state, so that the fluid flowing in the drainage channel 131 may also be guided out from top to bottom to the first water outlet channel 14 in the water cavity 13 in a nonlinear state, firstly, the drainage channel 131 extends from top to bottom, increasing the upper and lower flow empty paths, and secondly, the drainage channel 131 extends in a nonlinear state, that is, even if the fluid flows roundabout, increasing the length of the flow path, and also slowing down the flow velocity, so as to increase the flow area and time of the fluid in the water-vapor separation box 10, and improve the water-vapor separation effect.

In addition, since the top inlet of the exhaust channel 132 extends to the top of the water chamber 13 and the drainage channel 131 guides the water flow from top to bottom, the inlet of the exhaust channel 132 can discharge separated steam, thereby avoiding dripping caused by the water flow guided out from the top inlet of the exhaust channel 132.

It will be apparent to those skilled in the art from this disclosure that various other changes and modifications can be made which are within the scope of the utility model as defined in the appended claims.

Claims (11)

1. The water-vapor separation component is characterized by comprising a separation box, wherein a water cavity is arranged in the separation box, and the top end of the separation box is provided with a water inlet; the bottom end of the separation box is provided with a first water outlet channel; the top end of the first water outlet channel is communicated with the bottom end of the water cavity; a drainage channel and an exhaust channel are arranged in the water cavity, and one end of the drainage channel is communicated with the water inlet; the drainage channel extends from top to bottom in a nonlinear state in the water cavity so as to guide fluid to be guided out to the first water outlet channel from top to bottom in a nonlinear state; the top end inlet of the exhaust channel is higher than the top end inlet of the first water outlet channel and extends to the top end of the water cavity; the bottom outlet of the exhaust passage extends to the bottom end of the separation box.

2. The water vapor separator assembly of claim 1, wherein the top open perimeter wall of the first water outlet channel is provided with first spoilers spaced apart.

3. The water vapor separator assembly of claim 1, further comprising a water spout nested outside the first water outlet channel; the inner wall of the water outlet nozzle and the outer wall of the first water outlet channel form a water outlet interval at intervals; at least two second water outlet channels are arranged in the water cavity, and the at least two second water outlet channels are symmetrically distributed around the first water outlet channel at intervals; the bottom end of the second water outlet channel is communicated with the water outlet at intervals; the top inlet of the second water outlet channel is higher than the top inlet of the first water outlet channel.

4. The water-vapor separation assembly of claim 3, wherein the inner wall of the water spout is provided with a plurality of positioning ribs circumferentially spaced about the central axis of the water spout, the positioning ribs being adapted to abut against the outer wall of the first water outlet channel; the bottom outlet of the first water outlet channel extends out of the bottom end of the water outlet nozzle.

5. The water vapor separator assembly of claim 3, wherein a plurality of notches are provided in a bottom outlet peripheral wall of the first water outlet channel; the notches are circumferentially distributed at intervals around the central axis of the first water outlet channel.

6. The water-vapor separation assembly of claim 3, wherein the inner wall of the water spout is provided with a plurality of positioning ribs circumferentially spaced about the central axis of the water spout, the positioning ribs being adapted to abut against the outer wall of the first water outlet channel; the bottom end of the first water outlet channel is inwards contracted in the water outlet nozzle; the inner wall of the water outlet nozzle is provided with a drainage surface which gradually inclines towards the first water outlet channel from top to bottom.

7. The water vapor separator assembly of claim 3, wherein the open top perimeter wall of the second outlet channel is provided with second spoilers spaced apart.

8. The water vapor separation assembly of any one of claims 1-7 wherein the bottom wall of the drainage channel extends helically from top to bottom; a drainage plate is arranged in the water cavity, and the side wall of the drainage plate close to the water inlet and the inner wall of the water cavity are spaced to form the drainage channel; the drainage plate extends along the extending direction of the drainage channel.

9. The water vapor separator assembly of any one of claims 1-7 wherein a top end of said separator cartridge is capped with a cover plate; the cover plate is provided with a drainage groove which is sunken towards the water cavity; the drainage groove is arranged corresponding to the top inlet of the exhaust channel; the inner peripheral wall of the drainage groove is provided with a guide surface which is used for guiding condensed water to avoid the top inlet of the exhaust channel.

10. The water vapor separator assembly of any one of claims 1-7 wherein said separator cartridge is provided with a pressure relief vent disposed on a side of said separator cartridge remote from said drainage channel.

11. A heater comprising the water vapor separation assembly of any one of claims 1-9.