阅读说明：本技术 一种高效快速薄膜蒸发器 (High-efficient quick film evaporator ) 是由 彭鹏 彭定云 叶军 林升炳 张家洪 于 2020-11-30 设计创作，主要内容包括：本发明提供了一种高效快速薄膜蒸发器,包括外壳、蒸发管组、排气器及分流器,蒸发管组设置在外壳内,排气器旋转设置在蒸发管组的蒸发管上,分流器对进入到蒸发室内的液氨进行分流,通过利用液氨自下向上流动产生的力带动安装在蒸发管上的排气器进行旋转,使得蒸发管上的液氨膜蒸发形成的气体可以快速的散去,避免气体阻挡,后续的液氨快速的在蒸发管上形成新的液氨膜,提高蒸发管的换热效率,并且配合分流器对液氨的分流作用,使得液氨分布的更加均匀,解决了气液转过过程中,气体对液体的阻碍的技术问题。(The invention provides a high-efficiency fast film evaporator which comprises a shell, an evaporation tube group, an exhaust device and a splitter, wherein the evaporation tube group is arranged in the shell, the exhaust device is rotatably arranged on an evaporation tube of the evaporation tube group, the splitter splits liquid ammonia entering an evaporation chamber, the exhaust device arranged on the evaporation tube is driven to rotate by utilizing the force generated by the liquid ammonia flowing from bottom to top, so that gas formed by evaporation of a liquid ammonia film on the evaporation tube can be quickly dispersed, gas blockage is avoided, a new liquid ammonia film is quickly formed on the evaporation tube by subsequent liquid ammonia, the heat exchange efficiency of the evaporation tube is improved, the splitter is matched with the splitting effect of the liquid ammonia, the liquid ammonia is more uniformly distributed, and the technical problem of blocking of the gas on the liquid in the gas-liquid rotation process is solved.)

1. A high-efficiency fast film evaporator comprises a cylindrical shell (1), an evaporating pipe group (2) is arranged in the shell (1), and the high-efficiency fast film evaporator is characterized in that the shell (1) comprises a cylinder main body (11) with two open ends, and a water cover A (12) and a water cover B (13) which are hermetically arranged at the open ends of the two ends of the cylinder main body (11), an input port (111) for inputting a refrigerant is arranged at the bottom of the cylinder main body (11), an output port (112) for outputting the refrigerant is arranged at the top of the cylinder main body (11), a liquid inlet (121) and a liquid outlet (122) are respectively arranged at the lower part and the upper part of the water cover A (12), two groups of partition plates (14) are horizontally arranged in the water cover A (12), and the water cover A (12) is divided into a liquid inlet area (123), a transfer area (124) and a liquid outlet area (125) by the partition, the liquid inlet area (123) is arranged right opposite to the liquid inlet (121), the liquid outlet area (125) is arranged right opposite to the liquid outlet (122), a group of partition plates (14) are horizontally arranged in the water cover B (13), the partition plates (14) divide the water cover B (13) into a communicating area A (131) and a communicating area B (132), the communicating area A (131) is communicated with the liquid inlet area (123) and the transferring area (124), the communicating area B (132) is communicated with the transferring area (124) and the liquid outlet area (125), the evaporating pipe group (2) is positioned in the cylinder main body (11), the evaporating pipe group (2) comprises a pipe plate (21), an evaporating pipe (22), a baffle plate (23) and a liquid supply pipe (24), the pipe plate (21) is respectively and hermetically arranged at openings at two ends of the cylinder main body (11), and the pipe plate (21) is matched with the cylinder main body (11) to form an evaporating chamber (113), the evaporation tubes (22) with two open ends are arranged between the tube plates (21), two ends of each evaporation tube (22) are respectively communicated with the space in the water cover A (12) and the space in the water cover B (13), the baffle plates (23) are sleeved on the evaporation tubes (22), the liquid supply tube (24) is arranged between the tube plates (21), the liquid supply tube (24) is communicated with the input port (111), and the lower part of the liquid supply tube (24) is provided with a liquid discharge hole (241);

the cover is equipped with air exhauster (3) that the rotation set up on evaporating pipe (22), just the below of feed pipe (24) is provided with shunt (4), shunt (4) are right feed pipe (24) exhaust liquid ammonia is shunted, and liquid ammonia after the reposition of redundant personnel is right the salt solution of circulation cools off in evaporating pipe (22), and liquid ammonia drive after the reposition of redundant personnel shunt (4) are rotatory.

2. A high efficiency fast film evaporator according to claim 1, wherein salt liquid is fed into the liquid inlet area (123) through the liquid inlet (121) and then discharged from the liquid outlet (122) through the communicating area a (131), the transferring area (124), the communicating area B (132) and the liquid outlet area (125) in sequence, and the salt liquid flows in a serpentine shape in the evaporating tube (22).

3. A high efficiency fast film evaporator according to claim 1 wherein the air exhausters (3) are spaced apart from each other, and between adjacent evaporation tubes (22), the air exhausters (3) are sleeved on any evaporation tube (22), and the air exhausters (3) are not sleeved on the other evaporation tube (22).

4. A high efficiency fast film evaporator according to claim 1 wherein the de-aerator (3) comprises:

the lantern rings (31), the lantern rings (31) are respectively arranged at two ends of the evaporation tube (22) in the length direction in a rotating mode; and

a plurality of vanes (32), a plurality of vanes (32) are equidistantly arranged between the collars (31) along the circumferential direction of the evaporation pipe (22).

5. A high efficiency fast film evaporator according to claim 4 wherein the root of any one of the blades (32) is provided with an arcuate abutment plate (33), the abutment plate (33) being in abutting engagement with the outer circumferential side wall of the evaporator tube (22).

6. A high efficiency fast film evaporator according to claim 5 wherein the distance from the root of the blade (32) of the exhauster (3) where the abutment plate (33) is not located to the circumferential side wall of the evaporator tube (22) is 2-10 mm.

7. A high efficiency fast film evaporator according to claim 1 wherein the flow divider (4) comprises:

the flow distribution plate (41) is arranged in an arc shape, the flow distribution plate (41) is positioned under the liquid supply pipe (24), the flow distribution plate (41) is arranged over against the liquid discharge hole (241) on the liquid supply pipe (24) and reflects the liquid ammonia sprayed out from the liquid discharge hole (241) to the evaporation pipe (22), and the flow distribution plate (41) is arranged on the baffle plate (23) in a sliding mode along the vertical direction; and

and the spring piece (42) is arranged at the lower end part of the flow distribution plate (41), and the spring piece (42) drives the flow distribution plate (41) to reset.

8. A high efficiency fast film evaporator according to claim 7 wherein the upper end surface of the flow distribution plate (41) is provided with a plurality of ribs (411) along its length, the ribs (411) being adapted to change the direction of reflection of the liquid ammonia.

9. The efficient fast film evaporator according to claim 7, wherein the two ends of the flow distribution plate (41) in the width direction are symmetrically provided with flow distribution grooves (43), the opening (431) on the side of the flow distribution groove (43) is arranged right opposite to the center line of the flow distribution plate (41), the upper end surface of the flow distribution groove (42) is provided with a plurality of flow distribution ports (432), the flow distribution ports (432) are provided with flow guide plates (433) which swing in a rotating manner, and the flow guide plates (433) are all positioned on one side of the corresponding evaporation tube (22) in the width direction.

Technical Field

The invention relates to the technical field of mechanical structures of film evaporators, in particular to a high-efficiency and quick film evaporator.

Background

The film evaporator adopts the climbing film evaporation principle, a refrigerant is injected into the evaporator through a liquid supply distribution system at the bottom of the evaporator and is evaporated, the evaporated gas carries fine refrigerant droplets to move upwards in the ascending process, the droplets contact the wall surface of the heat exchange tube to form high-efficiency evaporation, a large heat exchange coefficient can be achieved, high-efficiency heat transfer is realized, and a large amount of heat exchange area can be saved compared with the traditional shell-and-tube evaporator by adopting the film evaporator under the same heat exchange condition.

In chinese patent No. CN101785930B, a tubular film evaporator is disclosed, which comprises a casing, a feed inlet and a vacuum extraction opening are provided at the top of the casing, a discharge outlet is provided at the bottom of the casing, at least one set of evaporation units is provided below the feed inlet in the casing, each set of evaporation units includes a material receiving funnel and a heat exchange tube, the heat exchange tube is vertically disposed and inserted into a circular hole at the bottom of the material receiving funnel, an annular gap is left between the periphery of the heat exchange tube and the material receiving funnel, when polyester is produced, the material flows downwards from the annular gap left between the periphery of the heat exchange tube and the material receiving funnel, and flows downwards along the surface of the heat exchange tube in a film shape, meanwhile, heat exchange is performed between the material and the heat exchange tube, and by-products generated by.

However, in the process of evaporative cooling of the tubular thin film evaporator disclosed in the above patent, the escaped gas product is wrapped outside the heat exchange tube, which can prevent subsequent liquid from contacting the heat exchange tube, and even if the liquid wraps the heat exchange tube, the gas generated by the liquid heat exchange can affect the heat exchange efficiency of the liquid.

Disclosure of Invention

In order to solve the problems, the invention provides a high-efficiency and rapid thin-film evaporator, which drives an air exhauster arranged on an evaporation tube to rotate by utilizing the force generated by the liquid ammonia flowing from bottom to top, so that the gas formed by evaporating a liquid ammonia film on the evaporation tube can be rapidly dispersed, gas blockage is avoided, a new liquid ammonia film is rapidly formed on the evaporation tube by subsequent liquid ammonia, the heat exchange efficiency of the evaporation tube is improved, and the liquid ammonia is more uniformly distributed by matching with the shunting action of a diverter on the liquid ammonia, thereby solving the technical problem of obstruction of the gas on the liquid in the gas-liquid transferring process.

In order to achieve the purpose, the invention provides the following technical scheme:

a high-efficiency fast film evaporator comprises a cylindrical shell, an evaporating pipe group is arranged in the shell, the shell comprises a cylinder main body with two open ends and a water cover A and a water cover B which are hermetically arranged at the open ends of the cylinder main body, an input port for inputting a refrigerant is arranged at the bottom of the cylinder main body, an output port for outputting the refrigerant is arranged at the top of the cylinder main body, a liquid inlet and a liquid outlet are respectively arranged at the lower part and the upper part of the water cover A, two groups of clapboards are horizontally arranged in the water cover A, the clapboards divide the water cover A into a liquid inlet area, a transfer area and a liquid outlet area from bottom to top, the liquid inlet area is right opposite to the liquid inlet, the liquid outlet area is right opposite to the liquid outlet, a group of clapboards is horizontally arranged in the water cover B, and divide the water cover B into a communicating area A and a communicating, the communication area A is communicated with the liquid inlet area and the transfer area, the communication area B is communicated with the transfer area and the liquid outlet area, the evaporation pipe group is positioned in the cylinder main body and comprises pipe plates, evaporation pipes, baffle plates and liquid supply pipes, the pipe plates are respectively and hermetically arranged at openings at two ends of the cylinder main body, the pipe plates are matched with the cylinder main body to form an evaporation chamber, the evaporation pipes with openings at two ends are arranged between the pipe plates, two ends of each evaporation pipe are respectively communicated with spaces in the water cover A and the water cover B, the baffle plates are sleeved on the evaporation pipes, the liquid supply pipes are arranged between the pipe plates, the liquid supply pipes are communicated with the input ports, and the lower parts of the liquid supply pipes are provided with liquid discharge holes;

the cover is equipped with the air exhauster that rotates the setting on the evaporating pipe, just the below of feed pipe is provided with the shunt, the shunt is right feed pipe exhaust liquid ammonia shunts, and liquid ammonia after the reposition of redundant personnel is right the salt solution of circulation in the evaporating pipe cools off, and liquid ammonia after the reposition of redundant personnel drives the shunt is rotatory.

As an improvement, salt liquid is input into the liquid inlet area through the liquid inlet and then sequentially passes through the communicating area A, the transfer area, the communicating area B and the liquid outlet area to be discharged from the liquid outlet, and the salt liquid flows in the evaporating pipe in a snake shape.

As an improvement, the exhaust devices are arranged at intervals, between adjacent evaporation pipes, the exhaust device is sleeved on any evaporation pipe, and the exhaust device is not sleeved on the other evaporation pipe.

As a refinement, the exhaust stack includes:

the lantern rings are respectively and rotatably arranged at two ends of the evaporation tube in the length direction; and

the blades are arranged between the lantern rings at equal intervals along the circumferential direction of the evaporation tube.

As an improvement, the root of any blade is provided with an arc-shaped abutting plate, and the abutting plate is abutted and attached to the outer circumferential side wall of the evaporation tube.

As an improvement, the distance from the root of the blade on the exhaust ventilator, which is not provided with the abutting plate, to the circumferential side wall of the evaporation tube is 2-10 mm.

As an improvement, the flow splitter comprises:

the distribution plate is arranged in an arc shape and is positioned right below the liquid supply pipe, the distribution plate is arranged right opposite to the liquid discharge hole in the liquid supply pipe and reflects liquid ammonia sprayed from the liquid discharge hole to the evaporation pipe, and the distribution plate is arranged on the baffle plate in a sliding mode in the vertical direction; and

the spring piece is arranged at the lower end part of the flow distribution plate and drives the flow distribution plate to reset.

As an improvement, a plurality of convex strips are arranged on the upper end surface of the splitter plate along the length direction of the splitter plate, and the convex strips are used for changing the reflection direction of the liquid ammonia.

As an improvement, the two ends of the width direction of the splitter plate are symmetrically provided with splitter grooves, the openings of the side edges of the splitter grooves are right opposite to the central line of the splitter plate, the upper end face of each splitter groove is provided with a plurality of splitter ports, the splitter ports are provided with guide plates which swing in a rotating mode, and the guide plates are all located on one side of the width direction of the corresponding evaporating pipe.

The invention has the beneficial effects that:

(1) according to the invention, the force generated by the liquid ammonia flowing from bottom to top is utilized to drive the gas exhauster arranged on the evaporation tube to rotate, so that gas formed by evaporation of the liquid ammonia film on the evaporation tube can be quickly dispersed, gas blockage is avoided, a new liquid ammonia film is quickly formed on the evaporation tube by subsequent liquid ammonia, the heat exchange efficiency of the evaporation tube is improved, and the liquid ammonia is more uniformly distributed by matching with the shunting action of the diverter on the liquid ammonia, so that the technical problem of liquid blockage caused by gas in the gas-liquid transfer process is solved;

(2) according to the invention, the water cover A and the water cover B are separated by the partition plate to form the liquid inlet area, the transfer area, the liquid outlet area, the communication area A and the communication area B, so that salt liquid flows along a snake shape in the evaporation tube, the path of the salt liquid flowing in the evaporation tube is prolonged, the heat exchange between the salt liquid and liquid ammonia is more sufficient, and the cooling efficiency of the salt liquid is improved;

(3) according to the liquid ammonia distributor, liquid ammonia is distributed by reflection of the distributor, disordered reflected liquid flow can be formed by the distributed liquid ammonia, liquid flow is collided and ejected on the evaporation tube, so that a liquid film is formed on the surface of the evaporation tube, heat exchange work of the evaporation tube is facilitated, when external liquid supply equipment stops inputting the liquid ammonia into the evaporation chamber, the distributor can reset upwards by virtue of the spring piece, the liquid ammonia in the liquid supply tube is blocked by the distributor and then is input into the evaporation chamber, and the liquid ammonia is prevented from being gasified in the evaporation chamber to form higher air pressure, so that the influence on the input of next liquid ammonia is avoided;

(4) the distributor is provided with the splitter box, the splitter box is used for spraying liquid ammonia liquid flow to the exhaust device, the liquid ammonia liquid flow is used for driving the exhaust device on the evaporation tube to rotate, in addition, the exhaust device on the upper evaporation tube is driven by liquid flow or gas flow formed by rotating and stirring the exhaust device on the lower part, and the exhaust devices interact with each other to form a plurality of vortexes for rapidly exhausting gas, so that the flowing of the gas is accelerated;

(5) when the exhaust device is arranged, the root parts of one group of blades are provided with the abutting plates, the root parts of the other groups of blades do not abut against the evaporation tube, a space is reserved, and the gas is driven to leave the evaporation tube by scraping the abutting plates on the outer circumference of the evaporation tube, so that the liquid ammonia can break through the blockage of the gas and is attached to the evaporation tube to form a liquid film.

In conclusion, the heat exchanger has the advantages of ingenious structure, good heat exchange effect and the like, and is particularly suitable for the technical field of heat exchange structures.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is a schematic view of the operation of the present invention;

FIG. 4 is a schematic perspective view of an evaporating tube set according to the present invention;

FIG. 5 is a schematic longitudinal cross-sectional view of an evaporator tube bank in accordance with the present invention;

FIG. 6 is a schematic view of the bottom structure of the evaporating tube set of the present invention;

FIG. 7 is a schematic perspective view of an exhaust stack according to the present invention;

FIG. 8 is a schematic cross-sectional view of an exhaust stack according to the present invention;

FIG. 9 is a schematic perspective view of a diverter according to the present invention;

fig. 10 is an enlarged view of a structure shown in fig. 9.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The first embodiment is as follows:

as shown in fig. 1 to 7, a high-efficiency fast film evaporator includes a cylindrical casing 1, an evaporation tube group 2 is disposed in the casing 1, and is characterized in that the casing 1 includes a cylindrical main body 11 with two open ends, and a water cap a12 and a water cap B13 hermetically disposed at the two open ends of the cylindrical main body 11, an input port 111 for inputting a refrigerant is disposed at the bottom of the cylindrical main body 11, an output port 112 for outputting the refrigerant is disposed at the top of the cylindrical main body 11, a liquid inlet 121 and a liquid outlet 122 are respectively disposed at the lower portion and the upper portion of the water cap a12, two sets of partition plates 14 are horizontally disposed in the water cap a12, the partition plates 14 divide the water cap a12 into a liquid inlet area 123, a transition area 124 and a liquid outlet area 125 from bottom to top, the liquid inlet area 123 is disposed opposite to the liquid inlet 121, and the liquid outlet area 125 is opposite to the liquid outlet 122, a group of partition plates 14 are horizontally arranged in the water cover B13, the partition plates 14 divide the water cover B13 into a communication area a131 and a communication area B132, the communication area a131 is communicated with the liquid inlet area 123 and the transition area 124, the communication area B132 is communicated with the transition area 124 and the liquid outlet area 125, the evaporation tube group 2 is positioned in the cylinder body 11, the evaporation tube group 2 comprises a tube plate 21, evaporation tubes 22, baffle plates 23 and liquid supply tubes 24, the tube plate 21 is respectively and hermetically mounted at openings at two ends of the cylinder body 11, the tube plate 21 is matched with the cylinder body 11 to form an evaporation chamber 113, the evaporation tubes 22 with openings at two ends are arranged between the tube plate 21, two ends of the evaporation tubes 22 are respectively communicated with spaces in the water cover a12 and the water cover B13, the baffle plates 23 are sleeved on the evaporation tubes 22, and the liquid supply tubes 24 are arranged between the tube plates 21, the liquid supply pipe 24 is communicated with the input port 111, and a liquid discharge hole 241 is formed at the lower part of the liquid supply pipe 24;

the cover is equipped with the air exhauster 3 that the rotation set up on the evaporating pipe 22, just the below of feed pipe 24 is provided with shunt 4, shunt 4 is right feed pipe 24 exhaust liquid ammonia shunts, and liquid ammonia after the reposition of redundant personnel is right the salt solution of circulation cools off in the evaporating pipe 22, and the liquid ammonia drive after the reposition of redundant personnel 4 are rotatory.

As shown in fig. 3, as an improvement, after the salt liquid is inputted into the liquid inlet area 123 through the liquid inlet 121, the salt liquid is discharged from the liquid outlet 122 through the communicating area a131, the transition area 124, the communicating area B132 and the liquid outlet area 125 in sequence, and the salt liquid flows in a serpentine shape in the evaporation tube 22.

Further, the exhaust pipes 3 are arranged at intervals, between the adjacent evaporation pipes 22, the exhaust pipe 3 is sleeved on any one of the evaporation pipes 22, and the exhaust pipe 3 is not sleeved on the other evaporation pipe 22.

It should be noted that after the salt liquid is inputted into the liquid inlet area 123 from the liquid inlet 121, the salt liquid is transported by the evaporation tube 22, and sequentially circulates in the communicating area a131, the transition area 124, the communicating area B132, and the liquid outlet area 125, and after the cooling work of heat exchange is completed, the salt liquid is discharged from the liquid outlet 122, and liquid ammonia (refrigerant) is inputted into the evaporation chamber 113 through the input port 111, and cools the salt liquid in the evaporation tube 22, and after the heat exchange between the liquid ammonia and the salt liquid in the evaporation tube 22 is completed, the liquid state is converted into the gas state, and the gas state is outputted from the output port 112, and the liquid is again converted into the liquid for recycling in the compressor.

It is further described that, in the process of cooling the salt solution, the salt solution in the evaporation tube 22 exchanges heat with the liquid ammonia in the evaporation chamber 113, so that the liquid ammonia is converted from the liquid state to the gaseous state, the formed gas is not discharged in time to block the cooling effect of the subsequent liquid on the cooling tube, the gas exhauster 3 is driven to operate by the flow of the liquid ammonia, the gas at the periphery of the evaporation tube 22 is guided upwards in time to be discharged, and the heat exchange efficiency of the evaporation tube 22 can be improved.

As shown in fig. 7 and 8, as a preferred embodiment, the exhaust stack 3 includes:

the lantern rings 31 are respectively arranged at two ends of the evaporation tube 22 in the length direction in a rotating way; and

a plurality of vanes 32, a plurality of said vanes 32 are arranged between said collars 31 along the circumference of said evaporating tube 22 at equal intervals.

Further, the root of any blade 32 is provided with an arc-shaped abutting plate 33, and the abutting plate 33 is abutted and attached to the outer circumferential side wall of the evaporation tube 22.

Furthermore, the distance from the root of the blade 32 of the exhaust stack 3, on which the abutting plate 33 is not provided, to the circumferential side wall of the evaporation tube 22 is 2-10 mm.

It should be noted that, in the process of rotating around the evaporation tube 22, the gas is guided and separated from the outer wall of the evaporation tube 22 by the abutting plate 33, and then the liquid film is formed on the surface of the evaporation tube 22 by the subsequent supplement of the liquid ammonia, so as to perform efficient heat exchange.

As shown in fig. 9 and 10, as a preferred embodiment, the flow divider 4 includes:

the flow dividing plate 41 is arranged in an arc shape, the flow dividing plate 41 is positioned right below the liquid supply pipe 24, the flow dividing plate 41 is arranged right opposite to the liquid discharge hole 241 on the liquid supply pipe 24 and reflects the liquid ammonia sprayed from the liquid discharge hole 241 to the evaporation pipe 22, and the flow dividing plate 41 is arranged on the baffle plate 23 in a sliding manner along the vertical direction; and

and a spring piece 42, wherein the spring piece 42 is provided at a lower end portion of the flow distribution plate 41, and the spring piece 42 drives the flow distribution plate 41 to return.

Further, a plurality of convex strips 411 are arranged on the upper end surface of the flow distribution plate 41 along the length direction of the flow distribution plate, and the convex strips 411 are used for changing the reflection direction of the liquid ammonia.

Furthermore, splitter 43 is installed to splitter 41 broad width direction both ends symmetry, and the opening 431 of this splitter 43 side is just right splitter 41's central line sets up, and a plurality of diffluence pass 432 have been seted up to this splitter 42's up end, and this diffluence pass 432 department is provided with rotatory wobbling guide plate 433, and this guide plate 433 all is located the correspondence one side of evaporating pipe 22 broad width direction, the both sides of guide plate 433 are provided with the guide block 4331 the same rather than rotatory swing orbit, are provided with curved guide way on the guide block 4331, the guide way cooperates with guide post 4332, leads to the swing of guide plate 433 for guide plate 433 swings when liquid ammonia pressure is indefinite, swings, changes the liquid flow direction.

It should be noted that the splitter plate 41 reflects and scatters the liquid ammonia input from the liquid supply tube 24 to the evaporation chamber 113, the reflected liquid ammonia is sprayed to the evaporation tube 22 located at the bottom, and then a liquid film is formed on the evaporation tube 22 to cool the evaporation tube 22, and the exhaust device 3 on the evaporation tube 22 rotates by means of the liquid ammonia flow, so as to drive the gasified gas on the evaporation tube 22 to flow, and at the same time, to drive the scattered liquid ammonia droplets to continuously diffuse upward.

Further, at the beginning, the flow distribution plate 41 is abutted against the liquid discharge hole 241 of the liquid supply pipe 24 by the elastic action of the spring piece 42, and when the pressure of the liquid ammonia discharged from the liquid discharge hole 241 is acted on the flow distribution plate 41, the flow distribution plate 41 moves downward to perform flow distribution reflection processing on the liquid ammonia, and the flow distribution plate 41 is provided with a convex strip 411 for distributing the liquid ammonia to form an irregular flow direction.

It should be noted that, after the liquid ammonia output from the liquid supply pipe 24 hits the splitter plate 41, a part of the liquid ammonia enters the matching splitter groove 43 and is discharged to the outside through the splitter groove 43, so as to provide driving force for the exhaust fan 3, and thus the exhaust fan 3 operates smoothly.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.