CN220524261U - Double-effect refrigeration equipment and tower fan - Google Patents

Abstract

The application relates to double-effect refrigeration equipment and a tower fan, and relates to the technical field of tower fans. Comprises a liquid storage tank, an infusion driving piece, a wet curtain component and an atomization device. A first accommodating space is formed in the liquid storage tank; the infusion driving piece is arranged in the first accommodating space; the wet curtain component comprises a liquid inlet, a liquid outlet and a wet curtain body, wherein the liquid inlet and the liquid outlet are arranged on the wet curtain body; the atomizing device comprises an atomizing assembly and a mist outlet assembly, and the atomizing assembly is communicated with the mist outlet assembly; wherein, the liquid storage tank is communicated with the liquid inlet; the liquid outlet is communicated with the atomization component. Air can both be humidified and cooled in two stages of entering equipment and discharging from equipment, so that the cooling and refrigerating effect of the equipment is improved, and the problem that the cooling and refrigerating effect of the existing refrigerating equipment is low is solved.

Description

Double-effect refrigeration equipment and tower fan

Technical Field

The utility model relates to the technical field of tower fans, in particular to double-effect refrigeration equipment and a tower fan.

Background

The tower fan is also known as a convection fan. The tower fan forms a three-dimensional exchange system with outdoor air according to the principle of air flow, and is similar to a fan for blowing in a kitchen range, and the tower fan can supply air even without the fan.

The utility model patent with the publication number of CN214945139U relates to a humidifying structure of a tower fan, which is characterized by comprising a tower fan body, wherein a water tank, an atomizing module and a fan are arranged in an inner cavity at the bottom of the tower fan body, the fan is arranged at the bottom of the atomizing module, a water outlet of the water tank is connected to a water inlet of the atomizing module through a pipeline, a mist outlet of the atomizing module is connected to the mist outlet module through a corrugated pipe, the mist outlet module is fixed on an air outlet frame at the front part of the upper side of the tower fan body, the mist outlet module is a mist outlet nozzle fixed at the upper part of the air outlet frame or a swing blade mist collecting box fixed on the air outlet frame, and a plurality of groups of mist outlets which are arranged in an up-down equidistant manner are arranged on the front end surface of the swing blade mist collecting box. The existing tower fan is generally additionally provided with a humidifying and atomizing assembly to play a role in humidifying and cooling, but only depends on the humidifying effect of the humidifying and atomizing assembly, so that the cooling effect is not ideal.

Aiming at the related technology, the problem that the cooling and refrigerating effect of the existing refrigerating equipment is low exists.

Disclosure of Invention

In view of the shortcomings of the prior art, the utility model aims to provide double-effect refrigeration equipment and a tower fan, and aims to solve the problem that the existing refrigeration equipment is low in cooling and refrigerating effects.

The application provides a double-effect refrigeration equipment and tower fan adopts following technical scheme: a double-effect refrigeration device and a tower fan, comprising:

the liquid storage device comprises a liquid storage tank, wherein a first accommodating space is formed in the liquid storage tank and used for storing cooling liquid;

the infusion driving piece is arranged in the first accommodating space;

the wet curtain assembly comprises a liquid inlet, a liquid outlet and a wet curtain body, wherein the liquid inlet and the liquid outlet are both arranged on the wet curtain body;

the atomization device is used for atomizing the cooling liquid and comprises an atomization assembly and a mist outlet assembly, and the atomization assembly is communicated with the mist outlet assembly;

the liquid storage tank is communicated with the liquid inlet and used for enabling the cooling liquid to flow into the wet curtain assembly through the liquid storage tank;

the liquid outlet is communicated with the atomization assembly and used for enabling the cooling liquid to flow into the atomization device through the wet curtain assembly.

Optionally, the liquid storage tank includes a liquid storage outer shell and a liquid storage inner shell, a first accommodating space is formed in the liquid storage outer shell, the liquid storage inner shell is arranged in the first accommodating space, a second accommodating space is formed in the liquid storage inner shell, the second accommodating space is communicated with the first accommodating space, one end of the liquid storage inner shell is arranged at the top of the liquid storage outer shell, the other end of the liquid storage inner shell is close to the bottom of the liquid storage outer shell, and the cooling liquid in the first volume weight space flows into the second accommodating space;

the infusion driving piece is arranged at one end of the liquid storage inner shell, which is close to the bottom of the liquid storage outer shell;

a first infusion tube is arranged between the liquid storage inner shell and the liquid inlet, one end of the first infusion tube is communicated with the liquid inlet, and the other end of the first infusion tube is communicated with the liquid storage inner shell.

Optionally, the atomization assembly includes an atomization box and an atomization piece, a third accommodating space is formed in the atomization box, and the atomization piece is arranged in the third accommodating space;

the atomizing box sets up in the first accommodation space, the atomizing box sets up stock solution shell top, the atomizing box lateral wall is provided with the leakage fluid dram.

Optionally, the atomizing box is disposed between the liquid storage inner shell and the liquid storage outer shell, and the first infusion tube passes through the third accommodating space and is communicated with the liquid storage inner shell

Optionally, the double-effect refrigeration tower fan further comprises a mounting piece, and the liquid storage tank, the wet curtain component and the atomization device are all arranged on the mounting piece;

wherein, the liquid reserve tank with the setting can be dismantled to the installed part.

Optionally, the liquid storage tank is in embedded fit with the mounting piece;

the liquid storage shell is provided with an embedded plate, the mounting piece is provided with an embedded groove matched with the embedded plate, one side of the embedded plate matched with the embedded groove is provided with a guide inclined plane, and the guide inclined plane is used for guiding the embedded plate to be matched with the embedded groove;

the liquid storage shell is provided with a first infusion port which is communicated with the first volume weight space.

Optionally, a disassembly gap is formed on the side surface of the liquid storage shell.

Optionally, the liquid inlet is arranged at the top end of the wet curtain body, and the liquid outlet is arranged at the bottom end of the wet curtain body.

Optionally, the wet curtain assembly further comprises a water diversion groove, the water diversion groove is arranged at the top end of the wet curtain body, and the liquid inlet is communicated with the water diversion groove;

at least one partition plate is arranged in the water diversion channel, and the partition plate is divergently arranged around by taking the liquid inlet as a concentration point.

The utility model also provides a tower fan which is characterized by comprising the double-effect refrigeration equipment.

Compared with the prior art, the embodiment of the utility model has the following advantages: the cooling liquid in the liquid storage tank flows into the wet curtain body through the liquid inlet under the action of the infusion driving piece, air can be humidified and cooled after passing through the wet curtain body, and when discharged again, the refrigerating effect can be achieved;

the cooling liquid which is not completely carried out in the wet curtain component flows into the atomization component through the liquid outlet, is discharged to the outside after being atomized by the atomization component, can achieve the aim of refrigerate again, improves the refrigeration effect of the equipment, is beneficial to reducing the waste of water resources and improves the utilization rate of the cooling liquid;

and air can both be humidified and cooled in two stages of entering equipment and discharging from equipment, so that the cooling and refrigerating effect of the equipment is improved, and the problem of low cooling and refrigerating effect of the existing refrigerating equipment is solved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present utility model, and other drawings may be obtained according to the drawings without inventive effort to those skilled in the art.

Fig. 1 is a schematic diagram of the overall structure of a dual-effect refrigeration apparatus according to an embodiment of the present application;

fig. 2 is a schematic diagram of the structure of a liquid storage tank of the double-effect refrigeration apparatus in the embodiment of the present application;

fig. 3 is a cross-sectional view of a liquid reservoir of a dual effect refrigeration appliance in an embodiment of the present application;

fig. 4 is a schematic view of the wet curtain assembly of the dual effect refrigeration appliance of the embodiment of the present application;

fig. 5 is a top view of the wet curtain pack price of the dual effect refrigeration appliance of the embodiment of the present application;

fig. 6 is a schematic structural diagram of an atomizing device of a double-effect refrigeration apparatus according to an embodiment of the present application;

fig. 7 is a schematic view of the structure of a mounting member of the dual-effect refrigeration appliance in an embodiment of the present application;

fig. 8 is a schematic view of the structure of the double-effect refrigeration equipment mounting of the embodiment of the present application at different angles;

fig. 9 is a schematic diagram of the cooperation of the mounting member of the dual-effect refrigeration appliance and the liquid storage tank in the embodiment of the present application.

Reference numerals illustrate:

1. a liquid storage tank; 11. a liquid storage housing; 111. an embedded plate; 1111. a guide slope; 1112. a second infusion port; 112. a first infusion port; 113. disassembling the notch; 114. a housing riser; 115. an infusion flow channel; 12. a liquid storage inner shell; 121. a fixing plate; 2. an infusion driving member; 3. a wet curtain assembly; 31. a liquid inlet; 32. a liquid outlet; 33. a wet curtain body; 34. a water diversion trench; 35. a water collection tank; 341. a partition plate; 342. a liquid inlet through hole; 4. an atomizing device; 41. an atomizing assembly; 411. an atomization box; 4111. a liquid outlet; 412. an atomizing member; 42. a mist outlet assembly; 5. a first infusion tube; 6. a mounting member; 61. a first mounting plate; 62. a second mounting plate; 63. installing a vertical plate; 631. embedded in the groove.

Detailed Description

In order to make the present utility model better understood by those skilled in the art, the following description will make clear and complete descriptions of the technical solutions of the embodiments of the present utility model with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The present application is described in further detail below in conjunction with the drawings attached to the specification.

The embodiment of the application discloses double-effect refrigeration equipment and a tower fan.

As shown in fig. 1, 3, 4 and 6, a dual effect refrigeration appliance includes a reservoir 1, an infusion drive unit 2, a wet curtain assembly 3 and an atomizing device 4. A first accommodating space is formed in the liquid storage tank 1 and is used for storing cooling liquid; the transfusion driving piece 2 is arranged in the first accommodating space; the wet curtain assembly 3 comprises a liquid inlet 31, a liquid outlet 32 and a wet curtain body 33, wherein the liquid inlet 31 and the liquid outlet 32 are arranged on the wet curtain body 33; the atomizing device 4 is used for atomizing the cooling liquid, the atomizing device 4 comprises an atomizing assembly 41 and a mist outlet assembly 42, and the atomizing assembly 41 is communicated with the mist outlet assembly 42; wherein the liquid storage tank 1 is communicated with the liquid inlet 31 and is used for cooling liquid to flow into the wet curtain assembly 3 through the liquid storage tank 1; the liquid outlet 32 communicates with the atomizing assembly 41 for the flow of cooling liquid through the wet curtain assembly 3 into the atomizing device 4.

The cooling liquid in the liquid storage tank 1 flows into the wet curtain body 33 through the liquid inlet 31 under the action of the transfusion driving piece 2, and air can be humidified and cooled after passing through the wet curtain body 33, and when discharged again, the refrigerating effect can be achieved.

The cooling liquid which is not completely carried out in the wet curtain component 3 flows into the atomization component 41 through the liquid outlet 32, is discharged to the outside after being atomized by the atomization component 41, can achieve the purpose of refrigerate again, improves the refrigeration effect of the equipment, is beneficial to reducing the waste of water resources, and improves the utilization rate of the cooling liquid.

And air can both be humidified and cooled in two stages of entering equipment and discharging from equipment, so that the cooling and refrigerating effect of the equipment is improved, and the problem of low cooling and refrigerating effect of the existing refrigerating equipment is solved.

Specifically, as shown in fig. 1, the overall shape of the liquid storage tank 1 is columnar, the wet curtain assembly 3 and the atomizing device 4 are both arranged above the liquid storage tank 1, and the wet curtain assembly 3 and the atomizing device 4 are oppositely arranged.

As shown in fig. 1 and 2, the liquid storage tank 1 includes a liquid storage outer shell 11 and a liquid storage inner shell 12, a first accommodating space is formed in the liquid storage outer shell 11, the liquid storage inner shell 12 is arranged in the first accommodating space, a second accommodating space is formed in the liquid storage inner shell 12, the second accommodating space is communicated with the first accommodating space, one end of the liquid storage inner shell 12 is arranged at the top of the liquid storage outer shell 11, the other end of the liquid storage inner shell 12 is close to the bottom of the liquid storage outer shell 11, and the cooling liquid in the first volume weight space flows into the second accommodating space.

The liquid storage shell 11 is provided with a first infusion port 112, and the first infusion port 112 is communicated with the first volume weight space.

As shown in fig. 2, the infusion driver 2 is disposed at an end of the inner reservoir housing 12 near the bottom of the outer reservoir housing 11.

As shown in fig. 1, 3 and 5, a first infusion tube 5 is arranged between the liquid storage inner shell 12 and the liquid inlet 31, one end of the first infusion tube 5 is communicated with the liquid inlet 31, and the other end is communicated with the liquid storage inner shell 12.

Specifically, as shown in fig. 1 and 3, the liquid storage inner shell 12 is located at the middle position of the liquid storage outer shell 11, and the overall shape of the liquid storage inner shell 12 is columnar. In this embodiment, the infusion driving member 2 is a water pump, and a fixing plate 121 is disposed on a side wall of the liquid storage inner shell 12 near the bottom, and the infusion driving member 2 is connected with the fixing plate 121 by bolts.

Under the drive of infusion driving piece 2, the coolant liquid in liquid reserve tank 1 is inhaled into first transfer line 5 to finally flow into in the wet curtain subassembly 3 and cool down, because infusion driving piece 2 sets up in the second accommodation space, and the space size in second accommodation space is less than the space size in first accommodation space, when the power of infusion driving piece 2 is certain like this, the drive power of infusion driving piece 2 drive coolant liquid is bigger, can be faster with the coolant liquid transport to in the wet curtain subassembly 3, has improved the cooling efficiency of equipment.

As shown in fig. 4 and 5, the liquid inlet 31 is disposed at the top end of the wet curtain body 33, and the liquid outlet 32 is disposed at the bottom end of the wet curtain body 33.

The wet curtain assembly 3 further comprises a water diversion groove 34, the water diversion groove 34 is arranged at the top end of the wet curtain body 33, and the liquid inlet 31 is communicated with the water diversion groove 34. At least one partition plate 341 is arranged in the water diversion channel 34, and the partition plate 341 is divergently arranged around by taking the liquid inlet 31 as a concentration point.

Specifically, as shown in fig. 4 and 5, the whole shape of the wet curtain body 33 is a curved rectangle, the wet curtain body 33 is vertically arranged above the liquid storage tank 1, the top end of the wet curtain body 33 is completely covered by the water diversion groove 34, the water diversion groove 34 partially extends out from the top end of the wet curtain body 33, and the liquid inlet 31 is formed at a corner of the edge of the extending part of the water diversion groove 34. In this embodiment, four partition plates 341 are disposed, and the four partition plates 341 are disposed in a manner of diverging from the liquid inlet 31 to the periphery, so that the top of the wet curtain body 33 is divided into four areas, and a liquid inlet through hole 342 is disposed at one end of the partition plate 341 away from the liquid inlet 31, so that the cooling liquid can flow into the wet curtain body 33 through the liquid inlet through hole 342.

The wet curtain body 33 bottom still is provided with water catch bowl 35, and the liquid outlet 32 sets up on water catch bowl 35.

After the cooling liquid flows into the water diversion channel 34 through the liquid inlet 31, the cooling liquid can be divided into four parts due to the existence of the partition plates 341, and flows into the liquid inlet through holes 342 corresponding to the respective partition plates 341, the cooling liquid wets the wet curtain body 33 through the liquid inlet through holes 342, so that the cooling and heat reduction of the equipment are facilitated, and the redundant cooling liquid flows into the water collection channel 35 through the bottom of the wet curtain body 33 under the influence of gravity to be collected, and finally enters the next procedure through the liquid outlet 32.

Due to the partition plate 341, the wet curtain body 33 can be uniformly soaked by the cooling liquid, and the phenomenon that the refrigeration effect is not ideal due to the fact that only part of the wet curtain body 33 is soaked is avoided.

As shown in fig. 3 and 6, the atomizing assembly 41 includes an atomizing tank 411 and an atomizing member 412, a third accommodating space is formed in the atomizing tank 411, and the atomizing member 412 is disposed in the third accommodating space. The atomizing case 411 sets up in first accommodation space, and atomizing case 411 sets up at stock solution shell 11 top, and atomizing case 411 lateral wall is provided with the leakage fluid dram 4111. The atomizing box 411 is disposed between the liquid storage inner shell 12 and the liquid storage outer shell 11, and the first infusion tube 5 passes through the third accommodating space to communicate with the liquid storage inner shell 12.

Specifically, as shown in fig. 3 and 6, the atomization box 411 has a columnar overall shape, and the atomizing member 412 is disposed at the bottom of the atomization box 411. The mist outlet assembly 42 is provided with a mist outlet, a mist outlet channel is arranged in the mist outlet assembly 42, one end of the mist outlet channel is communicated with the mist outlet, and the other end of the mist outlet channel is communicated with a third accommodating space of the atomizing box 411. After the atomized cooling liquid in the third accommodating space is atomized by the atomization piece 412, the atomized cooling liquid can enter the mist outlet channel and finally be sprayed to the outside from the mist outlet, so that cooling and heat reduction are realized.

As shown in fig. 3, 4 and 6, a second infusion tube is disposed between the liquid outlet 32 and the atomizing tank 411, one end of the second infusion tube is communicated with the liquid outlet 32, the other end is communicated with the third accommodating space, and the cooling liquid flowing out of the wet curtain assembly 3 flows into the third volume weight space through the second infusion tube, so that the cooling liquid is provided for atomizing the atomizing assembly 41.

The drain hole 4111 is formed in the side wall of the atomizing box 411, the drain hole 4111 is used for communicating the third accommodating space with the first accommodating space, and when excessive cooling liquid enters the atomizing box 411, the excessive cooling liquid can return to the liquid storage box 1 through the drain hole 4111 formed in the side wall of the atomizing box 411 so as to be reused. The distance from the liquid drain port 4111 to the bottom of the atomizing box 411 is between 35 mm and 40 mm, so that the atomized liquid can submerge the atomizing piece 412, and the atomized cooling liquid can be conveniently discharged from the atomizing box 411, and the atomizing efficiency of the atomizing piece 412 is improved.

The atomizing box 411 sets up between stock solution inner shell 12 top and stock solution shell 11 top, because go out liquid inner shell one end needs to be close to liquid outer shell bottom so that make full use of the coolant liquid in the stock solution case 1, so the length of stock solution inner shell 12 is certain, if set up atomizing box 411 again in first accommodation space, can make the space size in first accommodation space reduce, consequently set up atomizing box 411 between stock solution inner shell 12 top and stock solution outer shell 11 top, both can guarantee that infusion driving piece 2 draws the coolant liquid of stock solution case 1 bottom, can practice thrift the space in first volume weight space again, so as to deposit more coolant liquid.

As shown in fig. 1, 7, 8 and 9, the double-effect cooling tower fan further comprises a mounting piece 6, and the liquid storage tank 1, the wet curtain assembly 3 and the atomizing device 4 are all arranged on the mounting piece 6.

Wherein, the liquid storage tank 1 and the mounting piece 6 can be detachably arranged.

The liquid storage tank 1 is in embedded fit with the mounting piece 6.

The liquid storage housing 11 is provided with an insertion plate 111, the mount 6 is provided with an insertion groove 631 that mates with the insertion plate 111, a guide inclined surface 1111 is provided on a side of the insertion plate 111 that mates with the insertion groove 631, and the guide inclined surface 1111 is used to guide the insertion plate 111 to mate with the insertion groove 631.

The side of the liquid storage shell 11 is provided with a disassembly gap 113.

Specifically, as shown in fig. 1, 7, 8 and 9, the mounting member 6 includes a first mounting plate 61 and a second mounting plate 62, the first mounting plate 61 and the second mounting plate 62 are disposed in parallel up and down, the first mounting plate 61 and the second mounting plate 62 are connected by a mounting riser 63, and the mounting riser 63 is disposed vertically with respect to the first mounting plate 61 and the second mounting plate 62. The atomizing device 4 and the wet curtain assembly 3 are mounted on a first mounting plate 61, a second mounting plate 62 and a mounting riser 63.

Wherein the embedded groove 631 is provided on the mounting riser 63.

The mounting 6 sets up in liquid reserve tank 1 top surface top, and liquid reserve housing 11 top surface is provided with shell riser 114, and shell riser 114 sets up at liquid reserve housing 11 periphery border, and the overall shape of shell riser 114 is crooked rectangular plate. One side of the housing vertical plate 114 is fixedly connected with the liquid storage housing 11, the other side is provided with an embedded plate 111, and the embedded plate 111 is arranged in parallel with the top surface of the liquid storage housing 11. A second transfusion port 1112 is arranged above the embedded plate 111 and opposite to the first transfusion port 112, and the second transfusion port 1112 is connected with the first transfusion port 112 through a transfusion runner 115. When the mounting member 6 is mated with the tank 1, the first mounting plate 61 is positioned above the drop-in plate 111.

When it is necessary to convey the coolant into the tank 1, the disassembly gap 113 is grasped to move the tank 1 away from the mounting member 6, so that the tank 1 is disengaged from the mounting member 6, and at this time, the second fluid inlet 1112 is exposed, so that the coolant can be conveyed into the tank 1 through the second fluid inlet 1112.

The provision of the removal gap 113 facilitates disengagement of the reservoir 1 from the mounting member 6.

The detachable matching of the liquid storage tank 1 and the mounting piece 6 facilitates cleaning and replacement of the liquid storage tank 1, and the guiding inclined plane 1111 on the embedded plate 111 guides the liquid storage tank 1 to be matched with the mounting piece 6, so that the liquid storage tank 1 and the mounting piece 6 can be conveniently mounted.

When the mounting piece 6 is matched with the liquid storage tank 1, the first mounting plate 61 is located above the embedded plate 111, and the second liquid delivery port 1112 can be plugged through the first mounting plate 61, so that dust entering into the liquid storage tank 1 through the second liquid delivery port 1112 is effectively reduced.

The embodiment also comprises a tower fan which comprises the double-effect refrigeration equipment.

In summary, a dual-effect refrigeration apparatus includes a liquid storage tank 1, an infusion driving member 2, a wet curtain assembly 3, and an atomizing device 4. A first accommodating space is formed in the liquid storage tank 1 and is used for storing cooling liquid; the transfusion driving piece 2 is arranged in the first accommodating space; the wet curtain assembly 3 comprises a liquid inlet 31, a liquid outlet 32 and a wet curtain body 33, wherein the liquid inlet 31 and the liquid outlet 32 are arranged on the wet curtain body 33; the atomizing device 4 is used for atomizing the cooling liquid, the atomizing device 4 comprises an atomizing assembly 41 and a mist outlet assembly 42, and the atomizing assembly 41 is communicated with the mist outlet assembly 42; wherein the liquid storage tank 1 is communicated with the liquid inlet 31 and is used for cooling liquid to flow into the wet curtain assembly 3 through the liquid storage tank 1; the liquid outlet 32 communicates with the atomizing assembly 41 for the flow of cooling liquid through the wet curtain assembly 3 into the atomizing device 4.

The cooling liquid in the liquid storage tank 1 flows into the wet curtain body 33 through the liquid inlet 31 under the action of the transfusion driving piece 2, and air can be humidified and cooled after passing through the wet curtain body 33, and when discharged again, the refrigerating effect can be achieved.

The cooling liquid which is not completely carried out in the wet curtain component 3 flows into the atomization component 41 through the liquid outlet 32, is discharged to the outside after being atomized by the atomization component 41, can achieve the purpose of refrigerate again, improves the refrigeration effect of the equipment, is beneficial to reducing the waste of water resources, and improves the utilization rate of the cooling liquid.

And air can both be humidified and cooled in two stages of entering equipment and discharging from equipment, so that the cooling and refrigerating effect of the equipment is improved, and the problem of low cooling and refrigerating effect of the existing refrigerating equipment is solved.

It should be noted that, without conflict, the embodiments and features of the embodiments in the present application may be combined with each other.

It should be noted that the specific structure and working principle of the present utility model are described by taking a double-effect refrigeration device as an example, but the application of the present utility model is not limited to a double-effect refrigeration device, and the present utility model can also be applied to the production and the use of other similar workpieces.

It is to be understood that the utility model is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the utility model is limited only by the appended claims.

The foregoing description of the preferred embodiments of the utility model is not intended to limit the utility model to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the utility model are intended to be included within the scope of the utility model.

Claims (10)

1. A dual effect refrigeration appliance comprising:

the liquid storage device comprises a liquid storage tank, wherein a first accommodating space is formed in the liquid storage tank and used for storing cooling liquid;

the infusion driving piece is arranged in the first accommodating space;

the wet curtain assembly comprises a liquid inlet, a liquid outlet and a wet curtain body, wherein the liquid inlet and the liquid outlet are both arranged on the wet curtain body;

the atomization device is used for atomizing the cooling liquid and comprises an atomization assembly and a mist outlet assembly, and the atomization assembly is communicated with the mist outlet assembly;

the liquid storage tank is communicated with the liquid inlet and used for enabling the cooling liquid to flow into the wet curtain assembly through the liquid storage tank;

the liquid outlet is communicated with the atomization assembly and used for enabling the cooling liquid to flow into the atomization device through the wet curtain assembly.

2. The double-effect refrigeration device according to claim 1, wherein the liquid storage tank comprises a liquid storage outer shell and a liquid storage inner shell, a first accommodating space is formed in the liquid storage outer shell, the liquid storage inner shell is arranged in the first accommodating space, a second accommodating space is formed in the liquid storage inner shell, the second accommodating space is communicated with the first accommodating space, one end of the liquid storage inner shell is arranged at the top of the liquid storage outer shell, the other end of the liquid storage inner shell is close to the bottom of the liquid storage outer shell, and cooling liquid in the first accommodating space flows into the second accommodating space;

the infusion driving piece is arranged at one end of the liquid storage inner shell, which is close to the bottom of the liquid storage outer shell;

a first infusion tube is arranged between the liquid storage inner shell and the liquid inlet, one end of the first infusion tube is communicated with the liquid inlet, and the other end of the first infusion tube is communicated with the liquid storage inner shell.

3. The dual effect refrigeration appliance of claim 2 wherein said atomizing assembly includes an atomizing tank and an atomizing member, said atomizing tank having a third receiving space formed therein, said atomizing member being disposed within said third receiving space;

the atomizing box sets up in the first accommodation space, the atomizing box sets up stock solution shell top, the atomizing box lateral wall is provided with the leakage fluid dram.

4. The dual effect refrigeration appliance of claim 3 wherein said atomizing tank is disposed between said inner liquid storage housing and said outer liquid storage housing, said first fluid conduit passing through said third receiving space in communication with said inner liquid storage housing.

5. The dual effect refrigeration appliance of claim 2 wherein said dual effect refrigeration tower fan further includes a mounting member, said reservoir, said wet curtain assembly and said atomizing device all being disposed on said mounting member;

wherein, the liquid reserve tank with the setting can be dismantled to the installed part.

6. The dual effect refrigeration appliance of claim 5 wherein said reservoir is in flush engagement with said mounting member;

the liquid storage shell is provided with an embedded plate, the mounting piece is provided with an embedded groove matched with the embedded plate, one side of the embedded plate matched with the embedded groove is provided with a guide inclined plane, and the guide inclined plane is used for guiding the embedded plate to be matched with the embedded groove;

the liquid storage shell is provided with a first infusion port which is communicated with the first accommodating space.

7. The dual effect refrigeration appliance of claim 6 wherein said reservoir housing side is provided with a removal notch.

8. The dual effect refrigeration appliance of claim 1 wherein said liquid inlet is disposed at a top end of said wet curtain body and said liquid outlet is disposed at a bottom end of said wet curtain body.

9. The dual effect refrigeration appliance of claim 8 wherein said wet curtain assembly further includes a water diversion channel disposed at a top end of said wet curtain body, said liquid inlet communicating with said water diversion channel;

at least one partition plate is arranged in the water diversion channel, and the partition plate is divergently arranged around by taking the liquid inlet as a concentration point.

10. A tower fan comprising a double effect refrigeration apparatus according to any one of claims 1 to 9.