CN218065195U - Air supply device - Google Patents

Abstract

The utility model provides an air supply arrangement, air supply arrangement includes: the air conditioner comprises a shell, wherein an air inlet and an air outlet are formed in the shell; the condenser is arranged in the shell; the liquid storage structure is arranged on the shell and provided with a liquid outlet, and the liquid outlet corresponds to at least one part of the condenser. The utility model discloses a liquid accessible liquid outlet in the stock solution structure flows to the condenser, and liquid can play the effect of cooling to the condenser through the condenser to guarantee the heat transfer effect of condenser, be favorable to reducing air supply arrangement's energy consumption, and then be favorable to promoting air supply arrangement's work efficiency, be favorable to promoting the performance and the market competition of product. In addition, liquid in the stock solution structure flows to the condenser through the liquid outlet, can wash away the filth of condenser surface, plays the effect of clean condenser to guarantee the cleanliness on condenser surface, more do benefit to the contact of air current and condenser, and then be favorable to promoting the heat transfer effect of condenser.

Description

Air supply device

Technical Field

The utility model relates to an air supply arrangement technical field particularly, relates to an air supply arrangement.

Background

In the related art, the refrigeration fan includes a condenser, but no cooling measure is taken for the condenser in the operation process of the refrigeration fan, so that the temperature of the condenser is high, and the energy efficiency of the refrigeration fan is low.

SUMMERY OF THE UTILITY MODEL

The present invention aims at least solving one of the technical problems existing in the prior art or the related art.

Therefore, the utility model discloses an aspect provides an air supply arrangement.

In view of this, an aspect of the present invention provides an air supply device, including: the air conditioner comprises a shell, wherein an air inlet and an air outlet are formed in the shell; the condenser is arranged in the shell; the liquid storage structure is arranged on the shell and provided with a liquid outlet, and the liquid outlet corresponds to at least one part of the condenser.

The utility model provides a pair of air supply arrangement includes casing, condenser and stock solution structure. Wherein, the stock solution structure is equipped with the liquid outlet, and the liquid outlet corresponds the setting with at least partly of condenser, and like this, the liquid accessible liquid outlet in the stock solution structure flows to the condenser, and liquid can play the effect of cooling to the condenser through the condenser to guarantee the heat transfer effect of condenser, be favorable to reducing air supply arrangement's energy consumption, and then be favorable to promoting air supply arrangement's work efficiency, be favorable to promoting the performance and the market competition of product.

In addition, liquid in the stock solution structure flows to the condenser through the liquid outlet, can wash away the filth of condenser surface, plays the effect of clean condenser to guarantee the cleanliness on condenser surface, more do benefit to the contact of air current and condenser, and then be favorable to promoting the heat transfer effect of condenser.

It will be appreciated that the housing is provided with an air inlet and an air outlet, and that air from the external environment enters the housing through the air inlet, passes through the condenser and is exhausted through the air outlet.

According to the utility model discloses foretell air supply arrangement can also have following additional technical characterstic:

in the above technical solution, further, the air supply device further includes: a liquid supply structure; the pump body is arranged on the shell, and the liquid supply structure is communicated with the liquid storage structure through the pump body.

In the technical scheme, the air supply device further comprises a liquid supply structure and a pump body, the pump body is arranged on the shell and connected with the liquid supply structure, and the pump body is connected with the liquid storage structure. That is, the liquid supply structure and the liquid storage structure are communicated through the pump body. The pump body is with supplying the liquid pump in the liquid structure into the stock solution structure, and liquid in the stock solution structure flows to the condenser through the liquid outlet. That is to say, supply the liquid structure and can supply liquid to the stock solution structure through the pump body, like this, can guarantee the stock solution volume in the stock solution structure, can guarantee continuity and the validity of stock solution structure to the condenser cooling.

In any of the above technical solutions, further, the liquid supply structure includes: and the liquid receiving disc is positioned in the shell and is positioned below the condenser along the height direction of the shell, the disc opening of the liquid receiving disc is positioned on the peripheral side of the condenser, and the liquid receiving disc is communicated with the pump body.

In the technical scheme, the liquid supply structure comprises a liquid receiving disc, and the liquid receiving disc is located below the condenser along the height direction of the shell by limiting a matching structure of the liquid receiving disc and the condenser, and a disc opening of the liquid receiving disc is located on the peripheral side of the condenser. The condensate flowing over the outer surface of the condenser flows under the influence of gravity to a drip pan at the bottom of the condenser. Because connect the liquid dish and pump body intercommunication, the pump body can be with the liquid pump income stock solution structure in the liquid dish, promptly, has realized the cyclic utilization to the liquid that the stock solution structure flowed to the condenser, is favorable to reducing the liquid volume that is used for cooling and clear to the condenser, plays resource reuse's purpose.

Furthermore, the disc openings of the liquid receiving discs are positioned on the peripheral side of the condenser, so that liquid on the condenser can be ensured to completely and effectively flow to the liquid receiving discs under the action of gravity. This arrangement provides effective and reliable structural support for the recycling of liquid resources.

In any of the above technical solutions, further, the air supply device further includes: the first end of the liquid pumping pipe is connected with the pump body, and the second end of the liquid pumping pipe extends into the liquid receiving disc.

In this technical scheme, air supply arrangement still includes the liquid suction pipe, and the liquid suction pipe has first end and second end, and the pump body is connected to the first end of liquid suction pipe, and the second end of liquid suction pipe stretches into in the liquid receiving disc. That is, the pump body is connected with the liquid receiving disc through the liquid pumping pipe.

Specifically, connect the liquid dish and be equipped with liquid level limit line, the second end of liquid suction pipe stretches into liquid level limit line below to guarantee the validity and the feasibility of pump body drawing liquid.

In any of the above technical solutions, further, the liquid supply structure includes: and the liquid supply tank is communicated with the pump body.

In the technical scheme, the liquid supply structure comprises a liquid supply box, the liquid supply box is an independent box body structure and is communicated with the pump body, and the pump body can pump liquid in the liquid supply box into the liquid storage structure.

It is understood that the liquid supply tank has a liquid supply port through which liquid can be supplied into the liquid supply tank.

In any of the above technical solutions, further, the liquid supply tank is located at one side of the housing, and the liquid supply tank and the pump body are connected through a connecting pipe.

In this technical scheme, the supply tank is located one side of casing, can understand that supply tank and casing are two independent devices, and the supply tank is located the outside of casing.

In addition, the liquid supply tank and the pump body are connected through a connecting pipe, specifically, a first end of the connecting pipe is connected with the liquid supply tank, and a second end of the connecting pipe is connected with the pump body. It will be appreciated that the second end of the connecting tube is located within the housing and is connected to the pump body, and the first end of the connecting tube is located outside the housing and is connected to the supply tank.

Thus, whether the liquid supply tank is used or not can be determined according to specific actual use requirements. If the condenser is required to be cooled, the liquid supply tank and the pump body can be connected together through the connecting pipe. When the condenser is not required to be cooled, the liquid supply tank can be separated from the pump body. This setting makes air supply arrangement can satisfy the multiple user demand of user, is favorable to promoting the performance of product.

In any of the above technical solutions, further, the liquid supply tank is provided in the housing.

In this technical scheme, the casing is located to the liquid supply case, and the casing has the effect of support and fixed liquid supply case as the installation carrier of liquid supply case.

Specifically, the liquid supply tank is located within the housing. Or the liquid supply tank is arranged on the shell.

In any of the above technical solutions, further, the air supply device further includes: the evaporator is arranged in the shell, is closer to the top of the shell than the condenser and is connected with the condenser; the stock solution structure includes stock solution spare, and stock solution spare is located between evaporimeter and the condenser, and stock solution spare is equipped with liquid outlet and inlet, and at least partly and the evaporimeter of inlet correspond the setting.

In this technical scheme, air supply arrangement still includes the evaporimeter, and the stock solution structure includes stock solution spare, and stock solution spare is equipped with inlet and liquid outlet. Through the cooperation structure of reasonable setting evaporimeter, condenser and stock solution spare for along the direction of height of casing, stock solution spare is located between evaporimeter and the condenser, and the evaporimeter compares in the condenser top that is closer to the casing. That is, the evaporator is located above the condenser, and the liquid storage member is located above the condenser.

The condensed water dropping from the evaporator can flow to the liquid inlet of the liquid storage part under the action of gravity. Because the stock solution spare is equipped with the liquid outlet, and the liquid outlet corresponds the setting with the condenser, so, the comdenstion water in the stock solution spare can flow to the condenser through the liquid outlet. The effect that the comdenstion water can play the cooling to the condenser through the condenser to guarantee the heat transfer effect of condenser. Meanwhile, the condensed water flowing through the condenser can wash and clean the condenser, so that the cleanness of the condenser is ensured.

In any of the above technical schemes, further, the liquid storage piece is provided with a liquid storage tank, the notch of the liquid storage tank is positioned on the peripheral side of the evaporator, the notch of the liquid storage tank forms a liquid inlet, and the liquid storage tank is communicated with the liquid outlet.

In this technical scheme, through the cooperation structure of reasonable stock solution spare and the evaporimeter that sets up for the stock solution spare is equipped with the reservoir, and the notch of reservoir is located the week side of evaporimeter, can guarantee like this that the comdenstion water on the evaporimeter effectively flows to the reservoir under the action of gravity, and the comdenstion water in the reservoir of follow-up provides effective and reliable structural support through liquid outlet flow direction condenser.

In any of the above technical solutions, further, the pump body is communicated with the liquid storage part.

In the technical scheme, the pump body is communicated with the liquid storage part, and the liquid supply structure is communicated with the liquid storage part through the pump body. The pump body pumps the liquid in the liquid supply structure into the liquid storage part, and the liquid in the liquid storage part flows to the condenser through the liquid outlet. That is to say, supply the liquid structure and can supply liquid to stock solution spare through the pump body, like this, can guarantee the stock solution volume in the stock solution spare, can guarantee continuity and the validity of stock solution spare to the condenser cooling.

In any one of the above technical solutions, further, the liquid storage structure further includes: the liquid reserve tank is located one side of condenser, and the liquid reserve tank is equipped with the liquid outlet, and the liquid reserve tank and the pump body intercommunication.

In this technical scheme, the stock solution structure still includes the liquid reserve tank, and the liquid reserve tank is located one side of condenser, and the liquid reserve tank is an independent box structure, and the liquid reserve tank communicates with the pump body, supplies liquid structure and liquid reserve tank to pass through the pump body intercommunication. The pump body pumps the liquid in the liquid supply structure into the liquid storage tank, and the liquid in the liquid storage tank flows to the condenser through the liquid outlet. That is to say, supply the liquid structure and can supply liquid to the liquid reserve tank through the pump body, like this, can guarantee the stock solution volume in the liquid reserve tank, can guarantee continuity and the validity of liquid reserve tank to the condenser cooling.

In addition, because the liquid reserve tank is an independent box structure, the liquid in the liquid reserve tank can spray to condenser department through the liquid outlet with certain pressure under the effect of the pump body, has strengthened the contact dynamics of liquid with the surface of condenser, can strengthen the cooling effect to the condenser, and the reinforcing is favorable to promoting the cleanliness of wasing the condenser to the strength of erodeing of condenser.

Specifically, the liquid reserve tank staggers with stock solution spare and arranges, promptly, the liquid outlet of liquid reserve tank and the liquid outlet of stock solution spare can not sheltered from all.

In any of the above technical solutions, further, the liquid storage tank is provided with a plurality of nozzles, and a nozzle of each nozzle forms a liquid outlet.

In this technical scheme, because the liquid reserve tank is equipped with a plurality of nozzles, the spout of every nozzle forms the liquid outlet, and the nozzle has the effect of liquid that converges, more does benefit to liquid jet, is favorable to strengthening the scouring strength of liquid.

In any of the above technical solutions, further, the ejection directions of any two of the plurality of nozzles are different.

In this technical scheme, through the cooperation structure of reasonable a plurality of nozzles that sets up for the injection direction of two arbitrary nozzles in a plurality of nozzles is different, like this, can increase the spray regime of a plurality of nozzles, makes can spray the condenser from a plurality of directions and a plurality of angles, is favorable to promoting the cooling effect to the condenser, and strengthens the dynamics of washing away to the condenser, is favorable to promoting the cleanliness of wasing the condenser.

Of course, the ejection direction of the plurality of nozzles may be the same.

Alternatively, the ejection directions of some of the plurality of nozzles are the same.

In any of the above technical solutions, further, the air supply device further includes: and an inlet of the valve assembly is connected with the pump body, a first outlet of the valve assembly is connected with the liquid storage part, and a second outlet of the valve assembly is connected with the liquid storage tank.

In the technical scheme, the air supply device further comprises a valve assembly, the valve assembly is provided with an inlet, a first outlet and a second outlet, the inlet of the valve assembly is connected with the pump body, and the first outlet of the valve assembly is connected with the second outlet of the liquid storage component valve assembly and is connected with the liquid storage tank. The inlet of the valve component is communicated with the first outlet or the inlet of the valve component is communicated with the second outlet through switching, so that the pump body is communicated with the liquid storage part or the pump body is communicated with the liquid storage tank.

Specifically, the valve assembly includes a three-way valve.

Specifically, the air supply device is a fan, and more specifically, the air supply device is a cooling fan.

In any of the above technical solutions, further, the air supply device further includes: the wet curtain is arranged on the shell and is positioned at the evaporator; the liquid supply structure comprises a liquid supply pipe, and the liquid supply pipe can convey liquid to the wet curtain; the heat exchange piece can exchange heat with liquid in the liquid supply pipe.

In this technical scheme, this application has set up wet curtain, and wet curtain links to each other with the casing for the air current to flowing through the casing cools down to the cooperation evaporimeter reduces the temperature of the discharged cold air current of casing. Specifically, the wet curtain is arranged on the upwind side or the downwind side of the evaporator, so that the temperature of the finally discharged cold airflow for refrigeration can be reduced, and the refrigeration performance of the air supply device is improved. And then realize optimizing air supply arrangement's structure, promote air supply arrangement's performance.

The heat exchange piece can exchange heat with liquid in the liquid supply pipe, so that the heat exchange piece can cool the liquid in the liquid supply pipe, and the cooled liquid is conveyed to the wet curtain through the liquid supply pipe, so that the refrigerating performance of the air supply device is further improved.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The above and/or additional aspects and advantages of the present invention will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 shows a schematic structural diagram of an air supply device according to an embodiment of the present invention;

fig. 2 is a schematic partial structural view of an air supply device according to an embodiment of the present invention.

Wherein, the correspondence between the reference numbers and the component names in fig. 1 and fig. 2 is:

100 air supply device, 110 shell, 120 condenser, 130 liquid storage structure, 132 liquid outlet, 134 liquid storage part, 136 liquid inlet, 138 liquid storage tank, 140 liquid storage tank, 142 nozzle, 152 liquid receiving disc, 160 pump body, 170 liquid suction pipe, 180 evaporator, 190 valve component and 200 wet curtain.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention more clearly understood, the present invention will be described in further detail with reference to the accompanying drawings and detailed description. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced in other ways than those specifically described herein, and therefore the scope of the present invention is not limited by the specific embodiments disclosed below.

An air supply arrangement 100 according to some embodiments of the present invention is described below with reference to fig. 1 and 2.

Example 1:

as shown in fig. 1 and 2, an embodiment of an aspect of the present invention provides an air supply device 100 including a housing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

In detail, the air blowing device 100 includes a casing 110, a condenser 120, and a liquid storage structure 130. Wherein, stock solution structure 130 is equipped with liquid outlet 132, and liquid outlet 132 corresponds the setting with at least some of condenser 120, like this, liquid accessible liquid outlet 132 in the stock solution structure 130 flows to condenser 120, liquid can play the effect of cooling to condenser 120 through condenser 120 to guarantee condenser 120's heat transfer effect, be favorable to reducing air supply arrangement 100's energy consumption, and then be favorable to promoting air supply arrangement 100's work efficiency, be favorable to promoting the performance and the market competition of product.

In addition, the liquid in the liquid storage structure 130 flows to the condenser 120 through the liquid outlet 132, and can wash away the dirt on the outer surface of the condenser 120, so as to clean the condenser 120, ensure the cleanliness of the surface of the condenser 120, facilitate the contact between the air flow and the condenser 120, and further facilitate the heat exchange effect of the condenser 120.

It is understood that the housing 110 is provided with an air inlet and an air outlet, and air in the external environment enters the housing 110 through the air inlet, flows through the condenser 120, and is discharged through the air outlet.

Specifically, the air blowing device 100 includes a fan.

Further, as shown in fig. 1, the air blowing device 100 further includes: a wet curtain 200 provided at the case 110 and located at the evaporator 180; the liquid supply structure comprises a liquid supply pipe which can supply liquid to the wet curtain 200; the heat exchange piece can exchange heat with liquid in the liquid supply pipe.

Wherein, this application has set up wet curtain 200, and wet curtain 200 links to each other with casing 110 for the air current that flows through casing 110 cools down to the cooperation evaporimeter 180 reduces the temperature of the cold air current that casing 110 discharged. Specifically, the arrangement of the wet curtain 200 on both the upstream side and the downstream side of the evaporator 180 reduces the temperature of the finally discharged cold airflow for cooling, thereby improving the cooling performance of the air supply device 100. Further, the structure of the air supply device 100 is optimized, and the performance of the air supply device 100 is improved.

The heat exchange member can exchange heat with the liquid in the liquid supply pipe, so that the heat exchange member can cool the liquid in the liquid supply pipe, and the cooled liquid is conveyed to the wet curtain 200 through the liquid supply pipe, so as to further improve the refrigeration performance of the air supply device 100.

Example 2:

as shown in fig. 1 and 2, in addition to embodiment 1, embodiment 2 provides an air supply device 100 including a housing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

Further, as shown in fig. 1 and 2, the air supply device 100 further includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

In detail, the blower device 100 further includes a liquid supply structure and a pump body 160, the pump body 160 is disposed on the housing 110, the pump body 160 is connected to the liquid supply structure, and the pump body 160 is connected to the liquid storage structure 130. That is, the liquid supply structure and the liquid storage structure 130 communicate through the pump body 160. The pump body 160 pumps the liquid in the liquid supply structure into the liquid storage structure 130, and the liquid in the liquid storage structure 130 flows to the condenser 120 through the liquid outlet 132. That is to say, the liquid supply structure can supply liquid to the liquid storage structure 130 through the pump body 160, so that the liquid storage amount in the liquid storage structure 130 can be ensured, and the continuity and the effectiveness of the liquid storage structure 130 in cooling the condenser 120 can be ensured.

Example 3:

as shown in fig. 1 and 2, in addition to embodiment 2, embodiment 3 provides an air supply device 100 including a housing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

The blower 100 also includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

Further, as shown in fig. 1 and 2, the liquid supply structure includes a liquid receiving tray 152.

The liquid receiving pan 152 is located in the housing 110, the liquid receiving pan 152 is located below the condenser 120 in the height direction of the housing 110, the pan opening of the liquid receiving pan 152 is located on the peripheral side of the condenser 120, and the liquid receiving pan 152 is communicated with the pump body 160.

In detail, the liquid supply structure includes a liquid receiving tray 152, and the liquid receiving tray 152 is located below the condenser 120 and a tray opening of the liquid receiving tray 152 is located on a peripheral side of the condenser 120 along a height direction of the housing 110 by defining a matching structure of the liquid receiving tray 152 and the condenser 120. The condensed water flowing over the outer surface of the condenser 120 flows toward the drip pan 152 located at the bottom of the condenser 120 by gravity. Because the liquid receiving disc 152 is communicated with the pump body 160, the pump body 160 pumps the liquid in the liquid receiving disc 152 into the liquid storage structure 130, that is, the liquid flowing from the liquid storage structure 130 to the condenser 120 is recycled, so that the amount of the liquid for cooling and cleaning the condenser 120 is reduced, and the purpose of recycling resources is achieved.

In addition, the plate openings of the liquid receiving plate 152 are positioned on the peripheral side of the condenser 120, so that the liquid on the condenser 120 can be ensured to completely and effectively flow to the liquid receiving plate 152 under the action of gravity. This arrangement provides effective and reliable structural support for the recycling of liquid resources.

Specifically, air supply arrangement 100 still includes filtering the piece, and filtering the piece and locating the entrance of pump body 160, filtering the piece and be arranged in filth and the impurity of filtering in the liquid, be favorable to prolonging the life of product.

Further, as shown in fig. 2, the blowing device 100 further includes an extractor tube 170, a first end of the extractor tube 170 is connected to the pump body 160, and a second end of the extractor tube 170 extends into the liquid pan 152.

The blower 100 further includes a liquid pumping tube 170, the liquid pumping tube 170 has a first end and a second end, the first end of the liquid pumping tube 170 is connected to the pump body 160, and the second end of the liquid pumping tube 170 extends into the liquid receiving tray 152. That is, the pump body 160 is connected to the drip pan 152 through the suction pipe 170.

Specifically, the liquid receiving tray 152 is provided with a liquid level limiting line, and the second end of the liquid pumping pipe 170 extends below the liquid level limiting line to ensure the effectiveness and feasibility of the liquid pumping of the pump body 160.

Example 4:

as shown in fig. 1 and 2, in addition to embodiment 2, embodiment 4 provides an air supply device 100 including a housing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

The blower 100 also includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

Further, the liquid supply structure includes a liquid supply tank, and the liquid supply tank is communicated with the pump body 160.

In detail, the liquid supply structure includes a liquid supply tank, the liquid supply tank is an independent tank structure, the liquid supply tank is communicated with the pump body 160, and the pump body 160 pumps the liquid in the liquid supply tank into the liquid storage structure 130.

It will be appreciated that the supply tank has a supply port through which liquid can be supplied to the supply tank.

Example 5:

as shown in fig. 1 and fig. 2, in embodiment 4, the air supply device 100 provided by embodiment 5 includes a housing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

The blower 100 also includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

The liquid supply structure includes a liquid supply tank that communicates with the pump body 160.

Further, a liquid supply tank is located at one side of the housing 110, and the liquid supply tank and the pump body 160 are connected by a connection pipe.

In detail, the liquid supply tank is located at one side of the housing 110, and it is understood that the liquid supply tank and the housing 110 are two separate devices, and the liquid supply tank is located at the outer side of the housing 110.

In addition, the liquid supply tank and the pump body 160 are connected by a connection pipe, specifically, a first end of the connection pipe is connected to the liquid supply tank, and a second end of the connection pipe is connected to the pump body 160. It will be appreciated that a second end of the connecting tube is located within the housing 110 and is connected to the pump body 160, and a first end of the connecting tube is located outside the housing 110 and is connected to the supply tank.

Thus, whether the liquid supply tank is used or not can be determined according to specific actual use requirements. If the condenser 120 is to be cooled, the tank and the pump 160 may be connected together by a connecting pipe. The supply tank may be separated from pump body 160 when cooling of condenser 120 is not required. This arrangement enables the air supply device 100 to satisfy various user requirements, and is advantageous for improving the usability of the product.

Example 6:

as shown in fig. 1 and 2, in addition to embodiment 4, embodiment 6 provides an air supply device 100 including a housing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

The blower 100 also includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

The liquid supply structure includes a liquid supply tank that communicates with the pump body 160.

Further, the liquid supply tank is provided to the housing 110.

In detail, the liquid supply tank is provided in the housing 110, the housing 110 serves as a mounting carrier for the liquid supply tank, and the housing 110 functions to support and fix the liquid supply tank.

Specifically, the liquid supply tank is located within the housing 110. Or the liquid supply tank is provided on the housing 110.

Example 7:

as shown in fig. 1 and 2, in embodiment 2, the air supply device 100 provided by embodiment 7 includes a casing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

The blower 100 also includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

Further, the liquid supply structure includes: a liquid receiving tray 152 and a liquid supply tank. The liquid receiving pan 152 is located in the housing 110, the liquid receiving pan 152 is located below the condenser 120 in the height direction of the housing 110, a pan opening of the liquid receiving pan 152 is located on the peripheral side of the condenser 120, and the liquid receiving pan 152 is communicated with the pump body 160. The liquid supply tank communicates with the pump body 160. That is, both the liquid receiving tray 152 and the liquid supply tank can supply liquid to the liquid storage structure 130.

Example 8:

as shown in fig. 1 and 2, on the basis of any one of embodiments 2 to 7, embodiment 8 provides an air supply device 100 including a casing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

The blower 100 also includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

Further, as shown in fig. 1, the air supply device 100 further includes an evaporator 180.

The evaporator 180 is disposed in the housing 110, and the evaporator 180 is closer to the top of the housing 110 than the condenser 120, and the evaporator 180 is connected to the condenser 120.

The reservoir structure 130 includes a reservoir 134, the reservoir 134 is positioned between the evaporator 180 and the condenser 120, the reservoir 134 has a liquid outlet 132 and a liquid inlet 136, and at least a portion of the liquid inlet 136 is positioned in correspondence with the evaporator 180.

In detail, the air supply device 100 further includes an evaporator 180, and the liquid storage structure 130 includes a liquid storage part 134, and the liquid storage part 134 is provided with an inlet 136 and an outlet 132. By properly arranging the matching structures of the evaporator 180, the condenser 120 and the liquid storage part 134, the liquid storage part 134 is positioned between the evaporator 180 and the condenser 120 along the height direction of the shell 110, and the evaporator 180 is closer to the top of the shell 110 than the condenser 120. That is, the evaporator 180 is located above the condenser 120, and the liquid reservoir 134 is located above the condenser 120.

Condensate dripping from the evaporator 180 will flow under the force of gravity to the inlet 136 of the reservoir 134. Since the liquid outlet 132 is disposed on the liquid storage member 134, and the liquid outlet 132 is disposed corresponding to the condenser 120, the condensed water in the liquid storage member 134 flows to the condenser 120 through the liquid outlet 132. The condensed water flowing through the condenser 120 may cool the condenser 120, so as to ensure the heat exchange effect of the condenser 120. Meanwhile, the condensed water flowing through the condenser 120 may perform a washing function on the condenser 120, so as to ensure the cleanness of the condenser 120.

Further, as shown in fig. 1, the liquid storage member 134 is provided with a liquid storage tank 138, a notch of the liquid storage tank 138 is positioned on the periphery of the evaporator 180, the notch of the liquid storage tank 138 forms a liquid inlet 136, and the liquid storage tank 138 is communicated with the liquid outlet 132.

Wherein, through the cooperation structure of reasonable setting liquid storage piece 134 and evaporimeter 180 for liquid storage piece 134 is equipped with reservoir 138, and the notch of reservoir 138 is located the week side of evaporimeter 180, can guarantee like this that the comdenstion water on the evaporimeter 180 effectively flows to reservoir 138 under the action of gravity, provides effective and reliable structural support for the comdenstion water in follow-up reservoir 138 flows to condenser 120 through liquid outlet 132.

Example 9:

as shown in fig. 1 and 2, in addition to embodiment 8, embodiment 9 provides an air supply device 100 including a housing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

The blower 100 also includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

The air supply device 100 further includes an evaporator 180.

The evaporator 180 is disposed in the housing 110, and the evaporator 180 is closer to the top of the housing 110 than the condenser 120, and the evaporator 180 is connected to the condenser 120.

The liquid storage structure 130 includes a liquid storage part 134, the liquid storage part 134 is located between the evaporator 180 and the condenser 120, the liquid storage part 134 is provided with a liquid outlet 132 and a liquid inlet 136, and at least a portion of the liquid inlet 136 is disposed corresponding to the evaporator 180.

Further, as shown in fig. 1 and 2, the pump body 160 is in communication with the reservoir 134.

In detail, the pump body 160 communicates with the reservoir 134, and the liquid supply structure and the reservoir 134 communicate through the pump body 160. The pump 160 pumps the liquid in the liquid supply structure into the reservoir 134, and the liquid in the reservoir 134 flows through the outlet 132 to the condenser 120. That is to say, the liquid supply structure can supply liquid to the liquid storage part 134 through the pump body 160, so that the amount of liquid stored in the liquid storage part 134 can be ensured, and the continuity and the effectiveness of the liquid storage part 134 in cooling the condenser 120 can be ensured.

Example 10:

as shown in fig. 1 and 2, in addition to embodiment 8, embodiment 10 provides an air supply device 100 including a housing 110, a condenser 120, and a liquid storage structure 130.

The housing 110 is provided with an air inlet and an air outlet.

The condenser 120 is provided in the case 110.

The liquid storage structure 130 is disposed on the casing 110, the liquid storage structure 130 is provided with a liquid outlet 132, and the liquid outlet 132 is disposed corresponding to at least a portion of the condenser 120.

The blower 100 also includes a liquid supply structure and a pump body 160.

The pump body 160 is disposed in the housing 110, and the liquid supply structure and the liquid storage structure 130 are communicated through the pump body 160.

The air supply device 100 further includes an evaporator 180.

The evaporator 180 is disposed in the housing 110, and the evaporator 180 is closer to the top of the housing 110 than the condenser 120, and the evaporator 180 is connected to the condenser 120.

The reservoir structure 130 includes a reservoir 134, the reservoir 134 is positioned between the evaporator 180 and the condenser 120, the reservoir 134 has a liquid outlet 132 and a liquid inlet 136, and at least a portion of the liquid inlet 136 is positioned in correspondence with the evaporator 180.

Further, as shown in fig. 2, the liquid storage structure 130 further includes a liquid storage box 140, the liquid storage box 140 is located at one side of the condenser 120, the liquid storage box 140 is provided with a liquid outlet 132, and the liquid storage box 140 is communicated with the pump body 160.

In detail, the liquid storage structure 130 further includes a liquid storage tank 140, the liquid storage tank 140 is located at one side of the condenser 120, the liquid storage tank 140 is an independent tank structure, the liquid storage tank 140 is communicated with the pump body 160, and the liquid supply structure is communicated with the liquid storage tank 140 through the pump body 160. Pump 160 pumps the liquid from the liquid supply structure into tank 140, and the liquid in tank 140 flows through outlet 132 to condenser 120. That is, the liquid supply structure can supply liquid to the liquid storage tank 140 through the pump body 160, so that the amount of liquid stored in the liquid storage tank 140 can be ensured, and the continuity and effectiveness of the temperature reduction of the liquid storage tank 140 to the condenser 120 can be ensured.

In addition, because liquid storage tank 140 is an independent tank structure, liquid in liquid storage tank 140 can spray to condenser 120 department through liquid outlet 132 with certain pressure under the effect of pump body 160, has strengthened the contact dynamics of liquid with the surface of condenser 120, can strengthen the cooling effect to condenser 120, and strengthen the washing strength to condenser 120, is favorable to promoting the cleanliness that washs condenser 120.

Specifically, fluid reservoir 140 is offset from fluid reservoir 134, i.e., fluid outlet 132 of fluid reservoir 140 is unobstructed from fluid outlet 132 of fluid reservoir 134.

Further, as shown in fig. 2, the tank 140 is provided with a plurality of nozzles 142, and a spout of each nozzle 142 forms the liquid outlet 132.

Wherein, because liquid reserve tank 140 is equipped with a plurality of nozzles 142, the spout of each nozzle 142 forms liquid outlet 132, and nozzle 142 has the effect of converging liquid, more does benefit to liquid jet, is favorable to strengthening the scouring strength of liquid.

Further, the jetting directions of any two nozzles 142 of the plurality of nozzles 142 are different.

Wherein, through the cooperation structure of reasonable a plurality of nozzles 142 that sets up for two arbitrary nozzles 142's in a plurality of nozzles 142 injection direction is different, like this, can increase a plurality of nozzles 142's injection scope, makes can spray condenser 120 from a plurality of directions and a plurality of angles, is favorable to promoting the cooling effect to condenser 120, and strengthens the dynamics of scouring over condenser 120, is favorable to promoting the cleanliness of wasing condenser 120.

Of course, the plurality of nozzles 142 may have the same ejection direction.

Alternatively, the ejection directions of some of the plurality of nozzles 142 are the same.

Further, as shown in fig. 1 and 2, the blower device 100 further includes a valve assembly 190, an inlet of the valve assembly 190 is connected to the pump body 160, a first outlet of the valve assembly 190 is connected to the reservoir 134, and a second outlet of the valve assembly 190 is connected to the reservoir 140.

The air supply device 100 further includes a valve assembly 190, the valve assembly 190 has an inlet, a first outlet and a second outlet, wherein the inlet of the valve assembly 190 is connected to the pump body 160, and the first outlet of the valve assembly 190 is connected to the reservoir 134 and the second outlet of the valve assembly 190 is connected to the reservoir 140. The inlet of valve assembly 190 may be switched to communicate with the first outlet, or the inlet of valve assembly 190 may be switched to communicate with the second outlet, to allow pump body 160 to communicate with reservoir 134, or pump body 160 to communicate with reservoir 140.

Specifically, the valve assembly 190 includes a three-way valve.

Example 11:

the air blowing device 100 includes a cooling fan. The refrigeration fan includes an evaporator 180, a liquid storage structure 130, a condenser 120, a pump body 160, and a liquid supply structure.

Wherein the evaporator 180 is used for transporting cold. The reservoir structure 130 includes a reservoir 134 and the supply structure includes a drip pan 152. The reservoir 134 is configured to contain condensate dripping from the evaporator 180, and the outlet 132 of the reservoir 134 is configured to drip or spray the low-temperature condensate from the reservoir 138 of the reservoir 134 onto the condenser 120, the condensate flowing through the condenser 120 collecting in the drip pan 152 below the condenser 120. The pump body 160 may draw the condensed water in the drip pan 152 into the sump 138.

Specifically, the reservoir 134 is disposed just below the evaporator 180, and the condensed water from the evaporator 180 drips by gravity through the outlet 132 of the reservoir 134 onto the condenser 120, and the reservoir 134 also contains water that has been sucked up by the pump body 160.

Reservoir structure 130 includes a reservoir 134 and a tank 140. As shown in fig. 1 and 2, the reservoir 134 is of an open type structure, the reservoir 134 receives water sucked up by the pump body 160 and water dropped from the evaporator 180, and the reservoir 140 is of a closed type structure and receives water sucked up by the pump body 160.

The pump 160 is connected to a three-way valve, which can control the flow direction of the water sucked by the pump 160 to the liquid storage 134 or the liquid storage tank 140 under the control of the controller of the blower 100.

As the water flows toward the reservoir 134, the condensate is gravitationally combined with water dripping from the evaporator 180 and drips through the outlet 132 onto the condenser 120.

When water flows to the liquid storage tank 140, the water pressure of the pump body 160 can be received in the closed liquid storage tank 140 to affect the water pressure to be sprayed to the condenser 120 through the nozzle 142, so that the cooling effect on the condenser 120 is enhanced on one hand, and the dust on the condenser 120 can be washed and cleaned on the other hand.

The evaporator 180 absorbs the condensed water in the humid air at a low temperature, and in the refrigeration system, the temperature of the condenser 120 is higher, so the condensed water absorbed by the evaporator 180 can be utilized, and has two functions, namely, the cooling of the condenser 120 and the flushing of the condenser 120.

The condensed water of the evaporator 180 is sprayed onto the condenser 120, the temperature of the condenser 120 is reduced, the cold energy can be recycled, and the heat exchange effect of the whole machine is improved.

The pump body 160 is pressurized to accelerate the circulation efficiency of the condensed water, increase the pressure of the condensed water, and clean the condenser 120.

The condensed water absorbed by the evaporator 180 is collected by the liquid storage part 134, and then drops to the condenser 120 through the liquid outlet 132 of the liquid storage part 134 to cool the condenser 120.

The pump 160 sucks water (water after heat exchange of the condenser 120) from the liquid receiving tray 152 below the condenser 120, and conveys the water to the liquid storage part 134 below the evaporator 180 again, so as to further cool the condenser 120 by using the condensed water.

The pump 160 is pressurized and the water is rapidly sprayed at high pressure toward the condenser 120, which is an accelerated heat exchange and cleaning action for the condenser 120.

Specifically, the air supply device 100 includes a housing 110, a condenser 120, and a liquid storage structure 130. Wherein, stock solution structure 130 is equipped with liquid outlet 132, and liquid outlet 132 corresponds the setting with at least some of condenser 120, like this, liquid accessible liquid outlet 132 in the stock solution structure 130 flows to condenser 120, liquid can play the effect of cooling to condenser 120 through condenser 120 to guarantee condenser 120's heat transfer effect, be favorable to reducing air supply arrangement 100's energy consumption, and then be favorable to promoting air supply arrangement 100's work efficiency, be favorable to promoting the performance and the market competition of product.

In addition, liquid in the liquid storage structure 130 flows to the condenser 120 through the liquid outlet 132, dirt on the outer surface of the condenser 120 can be washed away, the effect of cleaning the condenser 120 is achieved, cleanliness of the surface of the condenser 120 is guaranteed, contact between air flow and the condenser 120 is facilitated, and the heat exchange effect of the condenser 120 is further improved.

In the present application, the term "plurality" means two or more unless expressly defined otherwise. The terms "mounted," "connected," "fixed," and the like are used broadly and should be construed to include, for example, "connected" may be a fixed connection, a detachable connection, or an integral connection; "connected" may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the description of the present specification, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (13)

1. An air supply device, comprising:

the air conditioner comprises a shell, wherein an air inlet and an air outlet are formed in the shell;

the condenser is arranged in the shell;

the liquid storage structure is arranged on the shell and provided with a liquid outlet, and the liquid outlet corresponds to at least one part of the condenser;

a liquid supply structure;

the pump body is arranged on the shell, and the liquid supply structure is communicated with the liquid storage structure through the pump body;

the liquid storage structure comprises:

the liquid reserve tank is located one side of condenser, the liquid reserve tank is equipped with the liquid outlet, just the liquid reserve tank with the pump body intercommunication.

2. The air supply arrangement of claim 1, wherein the liquid supply structure comprises:

connect the liquid dish, be located in the casing, follow the direction of height of casing, connect the liquid dish to be located the below of condenser, connect the dish mouth of liquid dish to be located the week side of condenser, connect the liquid dish with the pump body intercommunication.

3. The air supply apparatus of claim 2, further comprising:

the first end of liquid suction pipe is connected the pump body, the second end of liquid suction pipe stretches into in the liquid receiving disc.

4. The air supply arrangement of claim 1, wherein the liquid supply structure comprises:

and the liquid supply tank is communicated with the pump body.

5. The air supply arrangement according to claim 4,

the liquid supply tank is located on one side of the shell, and the liquid supply tank is connected with the pump body through a connecting pipe.

6. The air supply arrangement according to claim 4,

the liquid supply tank is arranged on the shell.

7. The air supply apparatus according to any one of claims 1 to 6, further comprising:

the evaporator is arranged in the shell, is closer to the top of the shell than the condenser and is connected with the condenser;

the stock solution structure includes stock solution spare, stock solution spare is located the evaporimeter with between the condenser, stock solution spare is equipped with liquid outlet and inlet, at least partly of inlet with the evaporimeter corresponds the setting.

8. The blowing device of claim 7,

the liquid storage part is provided with a liquid storage tank, a notch of the liquid storage tank is positioned on the peripheral side of the evaporator, the notch of the liquid storage tank forms the liquid inlet, and the liquid storage tank is communicated with the liquid outlet.

9. The air supply arrangement of claim 7,

the pump body is communicated with the liquid storage part.

10. The air supply arrangement of claim 7,

the liquid storage tank is provided with a plurality of nozzles, and the spout of each nozzle forms the liquid outlet.

11. The air supply arrangement of claim 10,

the jetting directions of any two nozzles of the plurality of nozzles are different.

12. The air supply apparatus of claim 7, further comprising:

and an inlet of the valve assembly is connected with the pump body, a first outlet of the valve assembly is connected with the liquid storage part, and a second outlet of the valve assembly is connected with the liquid storage tank.

13. The air supply apparatus of claim 7, further comprising:

the wet curtain is arranged on the shell and is positioned at the evaporator;

the liquid supply structure comprises a liquid supply pipe, and the liquid supply pipe can convey liquid to the wet curtain;

a heat exchange member capable of exchanging heat with liquid in the liquid supply tube.

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