CN219222802U - Condensate water utilization device and air conditioning system with same - Google Patents

Abstract

The utility model provides a condensate water utilization device and an air conditioning system with the condensate water utilization device, relates to the technical field of condensate water treatment, and is designed for solving the problem that the prior art lacks effective utilization of condensate water, so that resource waste is caused. This comdenstion water utilizes device includes sub-cooling module and heat exchange module, and the sub-cooling module includes the sub-cooling cavity and is used for the cooling sub-cooling component of sub-cooling cavity, and heat exchange module includes the heat exchange cavity with sub-cooling cavity intercommunication, and the heat exchange cavity is used for carrying out the heat exchange with article, and wherein, the water inlet has been seted up to the sub-cooling cavity, and the water inlet is used for the comdenstion water exit linkage with electrical apparatus, and the delivery port has been seted up to the heat exchange cavity, and the delivery port is used for being connected with water collector. The utility model realizes the effective utilization of condensed water and reduces the resource waste.

Description

Condensate water utilization device and air conditioning system with same

Technical Field

The utility model relates to the technical field of condensate water treatment, in particular to a condensate water utilization device and an air conditioning system with the condensate water utilization device.

Background

When some electric appliances with refrigeration function (such as an air conditioner) are used, condensed water with lower temperature can be generated in the electric appliances, and when the condensed water exceeds a certain water level, the condensed water can flow out. Due to the lack of effective utilization of condensed water, resource waste is caused.

Disclosure of Invention

A first object of the present utility model is to provide a condensate water utilizing apparatus, so as to solve the technical problem that the prior art lacks effective utilization of condensate water, thereby resulting in resource waste.

The utility model provides a condensate water utilization device, which comprises a sub-cooling module and a heat exchange module, wherein the sub-cooling module comprises a sub-cooling cavity and a sub-cooling element for cooling the sub-cooling cavity, the heat exchange module comprises a heat exchange cavity communicated with the sub-cooling cavity, the heat exchange cavity is used for carrying out heat exchange with an article, the sub-cooling cavity is provided with a water inlet, the water inlet is used for being connected with a condensate water outlet of an electric appliance, and the heat exchange cavity is provided with a water outlet, and the water outlet is used for being connected with a water collecting device.

By arranging a condensate water utilization device mainly composed of a sub-cooling module and a heat exchange module, taking the condensate water utilization device for recycling condensate water of an air conditioner as an example, when the air conditioner generates condensate water in the refrigerating process, the condensate water flows out through a condensate water outlet of the air conditioner and flows to a sub-cooling cavity of the sub-cooling module, and the condensate water entering the sub-cooling cavity is subjected to sub-cooling by a sub-cooling element so as to improve the cold quantity of the condensate water; then, the condensed water subjected to the secondary treatment enters a heat exchange cavity communicated with the secondary cavity, and is subjected to heat exchange with the article to cool the article, wherein the article for heat exchange with the heat exchange cavity can be food, a scalding article and the like; finally, the condensed water which completes the heat exchange with the articles in the heat exchange cavity flows out from the water outlet and is collected by the water collecting device, so that a user can use the condensed water collected by the water collecting device.

The condensate water utilization device utilizes the cold energy of the condensate water to cool down articles, collects the condensate water which participates in heat exchange, and uses the collected condensate water, so that the full utilization of the condensate water is realized in the whole process. The condensed water utilization device achieves the purpose of saving energy through repeated use of resources, thereby reducing resource waste.

Further, the heat exchange module further comprises a heat exchange coil, the heat exchange coil is detachably arranged in the heat exchange cavity, a first end of the heat exchange coil is used for receiving condensed water cooled by the sub-cooling cavity, and a second end of the heat exchange coil is connected with the water outlet. The heat exchange area can be increased by the arrangement, so that the cold energy in the condensed water can be dissipated more thoroughly.

Further, the heat exchange module further comprises a coil fixing frame, the heat exchange coil is fixedly connected with the coil fixing frame, one of the cavity wall of the heat exchange cavity and the coil fixing frame is provided with a clamping groove, the other one of the cavity wall of the heat exchange cavity and the coil fixing frame is provided with a clamping block, and the clamping block is fixedly clamped with the clamping groove. The setting need not to set up the screw, only can restrict the activity of heat exchange coil through the structure, has guaranteed the high efficiency of heat exchange coil installation and dismantlement.

Further, the first end of the heat exchange coil is connected with the sub-cooling cavity through a first hose, and the first end of the heat exchange coil is detachably and fixedly connected with the first hose; the second end of the heat exchange coil is connected with the water outlet through a second hose, and the second end of the heat exchange coil is detachably and fixedly connected with the second hose. Through the arrangement, pipelines at two ends of the heat exchange coil pipe have certain deformability, so that the position of the heat exchange coil pipe in the heat exchange cavity is convenient to adjust, install and fix, and conditions are created for taking out the heat exchange coil pipe.

Further, the heat exchange module further comprises a coil support frame, wherein the coil support frame is fixedly arranged in the heat exchange cavity and is used for supporting the heat exchange coil. The arrangement realizes the effective support of the heat exchange coil, thereby reducing the stress of the connection position of the coil fixing frame and the heat exchange cavity.

Further, the heat exchange module further comprises a shell and a tray body, wherein the shell is provided with an opening at the top, the tray body is openably covered on the opening at the top, the tray body is in butt joint with the shell to form the heat exchange cavity, and the tray body is at least partially arched towards the direction of the heat exchange cavity, so that a storage groove is formed in one surface of the tray body, which is away from the heat exchange cavity. Through above-mentioned setting, on the one hand, can utilize the disk body to realize the storage to the liquid, improve the use variety of disk body, on the other hand, can also increase the heat transfer area of disk body and heat transfer cavity.

Further, the sub-cooling module further comprises a branching heat exchange structure, the branching heat exchange structure is arranged in the sub-cooling cavity, the inlet end of the branching heat exchange structure is communicated with the water inlet, and the outlet end of the branching heat exchange structure is connected into the heat exchange cavity. This setting can effectively increase the comdenstion water at the inside heat transfer area of chamber that recoils for the component that recoils can fully cool off the comdenstion water, guarantees that the comdenstion water has sufficient cold volume.

Further, the sub-cooling module further comprises a water pump, the water pump is arranged in the sub-cooling cavity, a pump inlet of the water pump is connected with the water inlet, and a pump outlet of the water pump is connected with an outlet end of the branching heat exchange structure. The arrangement enables the condensed water entering from the water inlet to have enough pressure, thereby ensuring the smooth flow of the condensed water in the branching heat exchange structure and the heat exchange coil.

Further, at least one cavity wall of the sub-cooling cavity is provided with the sub-cooling element, the sub-cooling element comprises a semiconductor refrigerating sheet and a fan, the sub-cooling cavity is a closed cavity, the semiconductor refrigerating sheet is fixedly connected with the cavity wall of the sub-cooling cavity, the semiconductor refrigerating sheet is used for providing cold energy for the sub-cooling cavity, and the fan is used for blowing heat generated by the semiconductor refrigerating sheet to the external environment. The arrangement form of the re-cooling element not only can ensure the reliability of cooling the condensed water, but also has simple structure and is convenient for arrangement and layout.

Further, the sub-cooling module further comprises a mesh cover, the mesh cover is fixedly arranged outside the sub-cooling cavity, and the mesh cover wraps the semiconductor refrigerating sheet and the fan. The device can ensure that the heat of the semiconductor refrigerating sheet is effectively dissipated outwards, and can protect the semiconductor refrigerating sheet and the fan and reduce collision damage.

Further, the condensed water utilization device also comprises a filtering module, wherein the filtering module comprises a filtering cavity and a filter element, the filtering cavity is communicated with the water outlet, the filtering cavity is provided with a water outlet, and the water outlet is connected with the water collecting device through the water outlet; the filter element is arranged in the filter cavity, and the filter element is positioned in a flow path from the water outlet to the water outlet. By the arrangement, the condensed water can be sufficiently filtered and purified before entering the water collecting device.

Further, a taking and placing opening is formed in the cavity wall of the filter cavity, a baffle capable of being opened and closed is arranged at the taking and placing opening, and the filter element can be taken out and placed in the taking and placing opening. This setting is convenient for clean, change the filter core to make the filter core can be in the filtration state of preferred always, guarantee the filter effect.

Further, the filter module further comprises a filter box and a partition plate, the partition plate is arranged in the filter box, the inner space of the filter box is divided into a water diversion cavity and the filter cavity from top to bottom, the water diversion cavity is directly communicated with the water outlet, the filter cavity is directly communicated with the water outlet, and a plurality of water diversion holes distributed in a dispersed mode are formed in the partition plate. The whole process for condensate water can flow to the filter core comparatively evenly, avoids only locally playing the filter effect because of the filter core, on the one hand, guarantees the life of filter core, on the other hand, also prevents that the filter core from leading to the comdenstion water to flow unsmoothly because of local jam.

A second object of the present utility model is to provide an air conditioning system, so as to solve the technical problem that the prior art lacks effective utilization of condensed water of an air conditioner, thereby resulting in resource waste.

The air conditioning system comprises an air conditioner, a water collecting device and the condensate water utilizing device, wherein a water inlet of the condensate water utilizing device is connected with a condensate water outlet of the air conditioner, and a water outlet of the condensate water utilizing device is connected with the water collecting device.

By arranging the condensate water utilizing device in the air conditioning system, the air conditioning system has all advantages of the condensate water utilizing device, and accordingly, the condensate water utilizing device is not described in detail herein.

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 embodiments of the present utility model, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of an air conditioning system according to an embodiment of the present utility model;

FIG. 2 is an exploded view of a condensate water utilizing apparatus according to an embodiment of the present utility model;

FIG. 3 is a top view showing an internal structure of a condensate water utilizing apparatus according to an embodiment of the present utility model;

FIG. 4 is a side cross-sectional view of a heat exchange module of a condensate water utilizing apparatus provided by an embodiment of the present utility model;

FIG. 5 is a schematic view of the external structure of a condensate water utilizing apparatus according to an embodiment of the present utility model;

fig. 6 is an exploded view of a filter module of a condensate water utilizing apparatus according to an embodiment of the present utility model.

Reference numerals illustrate:

010-a condensate water utilization device; 020-air conditioner; 030-a water collection device; 040-drain; 050-a water collection pipe;

a 100-sub-cooling module; 200-a heat exchange module; 300-a filtration module; 400-a first hose; 500-a second hose;

110-a sub-cooling chamber; 111-water inlet; 120-a sub-cooling element; 121-semiconductor refrigerating sheets; 122-fans; 130-a shunt heat exchange structure; 140-a water pump; 150-mesh enclosure; 160-a filter;

210-a heat exchange cavity; 211-water outlet; 212-clamping grooves; 220-a tray body; 221-storage grooves; 230-a heat exchange coil; 240-coil fixing frame; 241-clamping blocks; 250-coil supporting frames; 260-a housing;

310-a filter cavity; 311-a water outlet; 320-a filter element; 330-baffle; 340-a filter cartridge; 350-dividing plates; 351-diversion holes; 360-diversion cavity.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Fig. 1 is a schematic structural diagram of an air conditioning system according to the present embodiment. As shown in fig. 1, the present embodiment provides an air conditioning system including an air conditioner 020, a water collecting device 030, and a condensed water utilizing device 010, specifically, a water inlet 111 of the condensed water utilizing device 010 is connected to a condensed water outlet of the air conditioner 020, and a water outlet 311 of the condensed water utilizing device 010 is connected to the water collecting device 030. Wherein, air conditioner 020 is the air pipe internal machine.

In the working process of the air conditioning system, condensed water generated by an air conditioner 020 enters a condensed water utilization device 010 through a condensed water outlet thereof, the condensed water utilization device 010 is effectively utilized, and the cold waste of the condensed water is reduced through heat exchange with high-temperature articles; after that, the condensed water after heat exchange is further introduced into the water collecting device 030, so that the user can use the condensed water collected by the water collecting device 030, and the waste of water sources is reduced.

It should be noted that, in this embodiment, the air conditioner 020 may be a home air conditioner or a multi-unit air conditioner.

With continued reference to fig. 1, in the present embodiment, the condensate outlet of the air conditioner 020 is connected to the water inlet 111 of the condensate utilizing device 010 through a water outlet pipe 040, and the water outlet 311 of the condensate utilizing device 010 is connected to the water collecting device 030 through a water collecting pipe 050.

Specifically, the water discharge pipe 040 can be a hose, and the position and the angle of the water discharge pipe 040 can be conveniently adjusted, so that the adaptability of the water discharge pipe 040 to the use environment is enhanced; similarly, the water collecting pipe 050 can also be a hose, and the position and the angle of the water collecting pipe 050 can be conveniently adjusted, so that the adaptability of the water collecting pipe 050 to the use environment is enhanced.

In this embodiment, a thin layer of foam cotton may also be wrapped around the exterior of the drain tube 040. By this arrangement, a certain heat-insulating effect can be provided to the drain pipe 040, so that the waste of the cold energy before the condensed water enters the condensed water utilizing device 010 through the drain pipe 040 can be reduced.

In this embodiment, the water collection device 030 may be an openable water tank, which is provided to facilitate the use of the collected condensed water by the user.

In the following description, the specific structure and operation principle of the condensed water utilizing apparatus 010 will be described in detail.

Fig. 2 is an exploded view of the structure of the condensate water usage apparatus 010 according to the present embodiment, and fig. 3 is a plan view of the internal structure of the condensate water usage apparatus 010 according to the present embodiment. As shown in fig. 2 and 3, the condensate water utilization apparatus 010 provided in this embodiment includes a sub-cooling module 100 and a heat exchange module 200, specifically, the sub-cooling module 100 includes a sub-cooling cavity 110 and a sub-cooling element 120 for cooling the sub-cooling cavity 110, the heat exchange module 200 includes a heat exchange cavity 210 communicated with the sub-cooling cavity 110, the heat exchange cavity 210 is used for performing heat exchange with an article, wherein the sub-cooling cavity 110 is provided with a water inlet 111, the water inlet 111 is connected with a condensate water outlet of an air conditioner 020, the heat exchange cavity 210 is provided with a water outlet 211, and the water outlet 211 is used for being connected with a water collecting apparatus 030.

When the air conditioner 020 generates condensed water in the refrigerating process, the condensed water flows out from a condensed water outlet of the air conditioner 020 and flows to the sub-cooling cavity 110 of the sub-cooling module 100, and the sub-cooling element 120 sub-cools the condensed water entering the sub-cooling cavity 110 to improve the cooling capacity of the condensed water; afterwards, the condensed water subjected to the re-cooling treatment enters a heat exchange cavity 210 communicated with the re-cooling cavity 110, and is subjected to heat exchange with the articles through the heat exchange cavity 210 to cool the articles, wherein the articles used for heat exchange with the heat exchange cavity 210 can be foods, scalding articles and the like; finally, the condensed water in the heat exchange chamber 210, which has completed heat exchange with the articles, flows out through the water outlet 211 and is collected by the water collecting device 030, so that the user uses the condensed water collected by the water collecting device 030.

The condensed water utilization device 010 utilizes the cold energy of the condensed water to cool down the articles, and collects the condensed water which participates in heat exchange so as to use the collected condensed water, and the whole process realizes the full utilization of the condensed water. The condensed water utilizing device 010 achieves the purpose of saving energy through repeated use of resources, thereby reducing resource waste.

In the present embodiment, only the use of the condensed water generated by the air conditioner 020 by the condensed water using device 010 is described, and it is to be understood that the condensed water using device 010 may be any other electric appliance that generates condensed water during operation, and the present embodiment uses only the use of the condensed water by the condensed water using device 010 as a specific example, and is not limited to the present application.

With continued reference to fig. 2 and 3, in this embodiment, the heat exchange module 200 may further include a heat exchange coil 230, specifically, the heat exchange coil 230 is detachably disposed in the heat exchange cavity 210, a first end of the heat exchange coil 230 is configured to receive the condensed water cooled by the sub-cooling cavity 110, and a second end of the heat exchange coil 230 is connected to the water outlet 211. That is, after the condensed water passes through the recooling of the recooling cavity 110, the condensed water enters the heat exchange coil 230 through the first end of the heat exchange coil 230, and exchanges heat with the articles by the heat exchange coil 230, so that the articles fully absorb the cold energy of the condensed water in the heat exchange cavity 210, and then the condensed water after heat exchange flows to the water outlet 211 through the second end of the heat exchange coil 230, so that the water collecting device 030 collects the condensed water.

By arranging the heat exchange coil 230 in the heat exchange cavity 210, the heat exchange area can be increased, so that the cold in the condensed water can be dissipated more thoroughly. Meanwhile, by arranging the heat exchange coil 230 in a detachable structure, the heat exchange coil 230 can be taken out from the heat exchange cavity 210 for cleaning and replacement after a period of use, and the maintenance convenience is improved.

Fig. 4 is a side cross-sectional view of the heat exchange module 200 of the condensate water utilization apparatus 010 provided by the present embodiment. Referring to fig. 2 and 3, and referring to fig. 4, in this embodiment, the heat exchange module 200 may further include a coil fixing frame 240, and the heat exchange coil 230 is fixedly connected with the coil fixing frame 240, wherein a cavity wall of the heat exchange cavity 210 is provided with a clamping groove 212, the coil fixing frame 240 is provided with a clamping block 241, and the clamping block 241 is clamped and fixed with the clamping groove 212.

The clamping block 241 and the clamping groove 212 are used for clamping the heat exchange coil 230 in the heat exchange cavity 210, so that the detachable fixed connection of the heat exchange coil 230 in the heat exchange cavity 210 can be realized, in addition, the screw is not required to be arranged, the movement of the heat exchange coil 230 can be limited only through the structure, and the installation and the detachment of the heat exchange coil 230 are high-efficiency.

In other embodiments, the clamping groove 212 may be formed in the coil fixing frame 240, and the clamping block 241 may be fixedly disposed on the cavity wall of the heat exchange cavity 210, so that the heat exchange coil 230 can be quickly installed and removed inside the heat exchange cavity 210 by using the clamping connection between the clamping block 241 and the clamping groove 212.

Referring to fig. 2 and 3, in the present embodiment, the number of the clamping slots 212 formed in the heat exchange cavity 210 is two, the two clamping slots 212 are formed in the same cavity wall of the heat exchange cavity 210, and accordingly, the number of the clamping blocks 241 disposed in the coil fixing frame 240 is also two, and the two clamping blocks 241 are respectively clamped and fixed with the two clamping slots 212 in a one-to-one correspondence. This arrangement can increase the number of connection points between the coil mount 240 and the heat exchange cavity 210, thereby ensuring stability of the heat exchange coil 230 during operation.

It should be noted that the number of the clamping slots 212 can be adjusted according to the actual size of the heat exchange cavity 210, and in this embodiment, only when the number of the clamping slots 212 is two, connection between the coil fixing frame 240 and the heat exchange cavity 210 is exemplarily described.

With continued reference to fig. 2 and 3, in the present embodiment, a first end of the heat exchange coil 230 is connected to the sub-cooling cavity 110 through a first hose 400, and the first end of the heat exchange coil 230 is detachably and fixedly connected to the first hose 400; the second end of the heat exchange coil 230 is connected to the water outlet 211 through a second hose 500, and the second end of the heat exchange coil 230 is detachably and fixedly connected to the second hose 500.

Through the above arrangement, the pipelines at the two ends of the heat exchange coil 230 have certain deformability, so that the position adjustment, installation and fixation of the heat exchange coil 230 in the heat exchange cavity 210 are facilitated, and the two ends of the heat exchange coil 230 are respectively arranged to be detachably and fixedly connected with the first hose 400 and the second hose 500, so that the connection limitation at the two ends of the heat exchange coil 230 is further facilitated to be disconnected, and then conditions are created for the taking out of the heat exchange coil 230.

In this embodiment, the "hose" refers to a pipe with stronger ductility, which can be extended under a certain tensile force and belongs to a connecting piece, so as to facilitate the layout of the heat exchange coil 230, ensure the communication of the pipe, and facilitate the removal of the heat exchange coil 230.

With continued reference to fig. 2 and 4, in the present embodiment, the heat exchange module 200 may further include a coil support 250, and specifically, the coil support 250 is fixedly disposed in the heat exchange cavity 210, and the coil support 250 is used for supporting the heat exchange coil 230.

The coil support 250 is arranged to effectively support the heat exchange coil 230, so that stress at the connection position of the coil fixing frame 240 and the heat exchange cavity 210 is reduced, and the installation stability of the heat exchange coil 230 is ensured.

Fig. 5 is a schematic view showing the external structure of the condensate water utilizing apparatus 010 according to the present embodiment. Referring to fig. 1 and fig. 4 in combination with fig. 5, in this embodiment, the heat exchange module 200 may further include a housing 260 and a tray body 220, specifically, the housing 260 has an opening at the top, the tray body 220 is openably covered on the opening at the top, the tray body 220 is butted with the housing 260 to form the heat exchange cavity 210, wherein the tray body 220 is partially arched in a direction of the heat exchange cavity 210, so that a storage groove 221 is formed on a surface of the tray body 220 facing away from the heat exchange cavity 210.

In the process of the condensed water utilizing apparatus 010 working, the user can place the object to be cooled in the storage groove 221 to realize the cooling treatment thereof. Through above-mentioned setting, on the one hand, can utilize disk body 220 to realize the storage to the liquid, improve disk body 220's use variety, if: placing normal-temperature water in the storage groove 221, and soaking the object to be cooled in the water in the storage groove 221; on the other hand, the structural form of the storage groove 221 can increase the heat exchange area of the tray 220 and the heat exchange cavity 210, so that the articles stored in the storage groove 221 can more fully utilize the cold energy of the condensed water in the heat exchange cavity 210, and the heat exchange efficiency is improved.

It should be noted that, in this embodiment, the tray 220 is only partially arched in the direction of the heat exchange cavity 210 in the middle portion, and in other embodiments, the tray 220 may be directly configured as a groove structure, that is: the tray 220 is entirely arched in the direction of the heat exchange chamber 210 to increase the storage capacity of the storage recess 221.

It should be further noted that the tray 220 may be configured with only one storage groove 221, but not limited thereto, and may take other configurations, such as: the plurality of positions of the tray body 220 are arranged to arch towards the direction of the heat exchange cavity 210, so that a plurality of storage grooves 221 are formed on one surface of the tray body 220 facing away from the heat exchange cavity 210, and the condensed water utilization device 010 can cool a plurality of groups of articles at the same time without causing mutual interference among the articles.

With continued reference to fig. 2 and 3, in the present embodiment, the sub-cooling module 100 may further include a branching heat exchange structure 130, specifically, the branching heat exchange structure 130 is disposed in the sub-cooling cavity 110, an inlet end of the branching heat exchange structure 130 is communicated with the water inlet 111, and an outlet end of the branching heat exchange structure 130 is connected to the heat exchange cavity 210.

In the operation process of the condensate water utilizing device 010, after entering from the water inlet 111, condensate water is split by the split heat exchanging structure 130 to form a plurality of branches in the sub-heat cavity 110, and finally enters the heat exchanging cavity 210 together. This arrangement can effectively increase the heat exchange area of the condensed water inside the sub-cooling chamber 110, so that the sub-cooling element 120 can sufficiently cool the condensed water, and ensure that the condensed water has sufficient cooling capacity.

With continued reference to fig. 2 and 3, in this embodiment, the sub-cooling module 100 may further include a water pump 140, specifically, the water pump 140 is disposed in the sub-cooling cavity 110, a pump inlet of the water pump 140 is connected to the water inlet 111, and a pump outlet of the water pump 140 is connected to an outlet end of the branching heat exchange structure 130.

The arrangement of the water pump 140, on one hand, ensures that the condensed water entering from the water inlet 111 has enough pressure, thereby ensuring the smooth flow of the condensed water in the branching heat exchange structure 130 and the heat exchange coil 230, and on the other hand, utilizes the integration of the water pump 140 in the condensed water utilization device 010, omits the complicated step of installing the water pump 140 on site, particularly for installing the water pump 140 in the special installation scene when the air conditioner 020 needs to be drained as soon as possible, greatly saves time and energy, and also avoids the defect that a user cannot normally use the air conditioner 020 in a short period.

With continued reference to fig. 2 and 3, in the present embodiment, two cavity walls of the sub-cooling cavity 110 are provided with sub-cooling elements 120, the sub-cooling elements 120 include a semiconductor cooling plate 121 and a fan 122, wherein the sub-cooling cavity 110 is a closed cavity, the semiconductor cooling plate 121 is fixedly connected with the cavity wall of the sub-cooling cavity 110, the semiconductor cooling plate 121 is used for providing cooling capacity for the sub-cooling cavity 110, and the fan 122 is used for blowing heat generated by the semiconductor cooling plate 121 to the external environment.

In the operation process of the condensate water utilizing device 010, the semiconductor refrigerating sheet 121 generates cold energy, so as to cool the condensate water in the sub-cooling cavity 110, thereby achieving the purpose of sub-cooling and improving the cold energy of the condensate water.

The sub-cooling cavity 110 is a closed cavity, and the semiconductor refrigeration sheet 121 exchanges heat with air with a certain vacuum degree in the sub-cooling cavity 110 to maintain the overall average temperature of the sub-cooling cavity 110, thereby meeting the sub-cooling requirement of condensed water; the fan 122 is used for blowing the heat generated by the semiconductor cooling fin 121 to the external environment, so as to rapidly and effectively dissipate the heat to the external environment, thereby ensuring that the semiconductor cooling fin 121 can always have better working performance.

This arrangement of the sub-cooling element 120 not only ensures the reliability of cooling down the condensed water, but also is simple in structure and convenient to set up and layout.

It should be noted that, in this embodiment, the sub-cooling element 120 is disposed on two adjacent sidewalls of the sub-cooling cavity 110, but the present utility model is not limited thereto, and other arrangements may be adopted, for example: the sub-cooling element 120 is disposed on one of the other walls of the sub-cooling cavity 110, or the sub-cooling elements 120 are disposed on a plurality of walls of the sub-cooling cavity 110, which can achieve the purpose of sub-cooling the condensed water in the sub-cooling cavity 110.

With continued reference to fig. 2 and 5, in the present embodiment, the sub-cooling module 100 may further include a mesh enclosure 150, specifically, the mesh enclosure 150 is fixedly disposed outside the sub-cooling cavity 110, and the mesh enclosure 150 wraps the semiconductor cooling fin 121 and the fan 122.

The setting of screen panel 150 on the one hand can guarantee that the heat that semiconductor refrigeration piece 121 produced gives off outwards effectively for semiconductor refrigeration piece 121 is in the performance of preferred all the time, thereby guarantees the effect of recooling, on the other hand can also play certain guard action to fan 122, avoids fan 122 to collide with and damage, also avoids simultaneously being injured because of the unexpected touching fan 122 of user, and the security is higher.

With continued reference to fig. 5, in this embodiment, the condensate water utilizing apparatus 010 may further include a filter 160, specifically, the filter 160 is disposed upstream of the water inlet 111, that is, the condensate water of the air conditioner 020 is filtered by the filter 160 before entering the recooling chamber 110 for recooling. The setting can effectively reduce the impurity that mixes in the comdenstion water, avoids the comdenstion water to take place stifled tub phenomenon at follow-up flow in-process to guarantee the smoothness nature that the comdenstion water flows.

Fig. 6 is an exploded view of the filter module 300 of the condensate water utilization apparatus 010 according to the present embodiment. With continued reference to fig. 2, and with reference to fig. 6, in this embodiment, the condensate water utilizing apparatus 010 may further include a filter module 300, specifically, the filter module 300 includes a filter cavity 310 and a filter element 320, the filter cavity 310 is communicated with the water outlet 211, and the filter cavity 310 is provided with a water outlet 311, so that the water outlet 211 is connected with the water collecting apparatus 030 through the water outlet 311; the filter element 320 is disposed inside the filter chamber 310, and the filter element 320 is located in a flow path of the condensed water from the water outlet 211 to the drain outlet 311.

In the working process of the condensate water utilizing device 010, the condensate water subjected to heat exchange in the heat exchange cavity 210 enters the filtering cavity 310 from the water outlet 211, the condensate water is filtered and purified by the filter element 320 in the filtering cavity 310, and then the filtered and purified condensate water flows out from the water outlet 311 and finally enters the water collecting device 030.

Through the arrangement, the condensed water can be sufficiently filtered and purified before entering the water collecting device 030, so that metal ions, other dust impurities, bacteria and the like mixed in the condensed water are reduced or even removed, and the cleanliness of the condensed water collected by the water collecting device 030 is ensured, so that various use requirements of users are met.

With continued reference to fig. 6, in this embodiment, a pick-and-place opening is formed in a cavity wall of the filter cavity 310, where the pick-and-place opening is provided with an openable baffle 330, and the filter element 320 can be taken out and put in through the pick-and-place opening.

After a period of use, the pick-and-place opening can be opened, the filter element 320 for a long time can be taken out, the replaced filter element 320 is placed from the pick-and-place opening, and then the pick-and-place opening is closed. This setting is convenient for clean, change filter core 320 to make filter core 320 can be in the filtration state of preferred always, guarantee the filter effect.

Referring to fig. 6, in this embodiment, the filter module 300 may further include a filter box 340 and a partition plate 350, specifically, the partition plate 350 is disposed inside the filter box 340, and separates an inner space of the filter box 340 into a water diversion cavity 360 and a filter cavity 310 from top to bottom, the water diversion cavity 360 is directly communicated with the water outlet 211, and the filter cavity 310 is directly communicated with the water outlet 311, wherein the partition plate 350 is provided with a plurality of water diversion holes 351 distributed in a dispersed manner.

By this arrangement, the condensed water flowing out from the water outlet 211 provided in the heat exchange cavity 210 is buffered in the water diversion cavity 360, and then flows downwards to the filter element 320 through the water diversion holes 351 distributed in a dispersed manner for filtration, and finally, the filtered condensed water flows from the water outlet 311 to the water collecting device 030. The whole process ensures that condensed water can flow to the filter element 320 relatively uniformly, and avoids the phenomenon that the condensed water flows unsmoothly due to local blockage of the filter element 320 because the filter element 320 only locally plays a role in filtering, so that the service life of the filter element 320 is ensured on one hand, and the filter element 320 is prevented from flowing unsmoothly due to local blockage on the other hand.

In this embodiment, the partition plate 350 is a strip-shaped plate, and the plurality of water diversion holes 351 are distributed along the length direction of the partition plate 350. This arrangement ensures as much as possible even filtration of the condensate by the filter element 320.

With continued reference to fig. 1 to 3, in the present embodiment, the condensate water utilizing apparatus 010 operates as follows: after the condensed water generated by the air conditioner 020 flows out, the condensed water flows to the condensed water utilizing device 010 through the water drain pipe 040, and is filtered once through the filter 160; secondly, the water inlet 111 of the self-condensation water utilization device 010 enters, and flows to the shunt heat exchange structure 130 under the pumping action of the water pump 140, in the process, the semiconductor refrigeration piece 121 works to generate cold energy, the average low temperature of the sub-cooling cavity 110 is maintained, the fan 122 works to blow the heat generated by the operation of the semiconductor refrigeration piece 121 to the external environment, the semiconductor refrigeration piece 121 is ensured to be always in better working performance, and thus sub-cooling treatment of the condensed water in the shunt heat exchange structure 130 is realized; afterwards, the condensed water after the sub-treatment enters the heat exchange coil 230 through the first hose 400, and continuously radiates cold outwards along with the flow in the heat exchange coil 230, and exchanges heat with the articles in the storage groove 221 of the tray body 220, so as to achieve the purpose of cooling the articles; subsequently, the condensed water after heat exchange enters the water diversion cavity 360 through the second hose 500, and further flows to the filter cavity 310 through the water diversion hole 351, and the condensed water at the moment is filtered again by the filter element 320 in the filter cavity 310; finally, the condensed water after filtration flows into the water collecting pipe 050 through the water outlet 311, and finally enters the water collecting device 030 to collect.

Although the present utility model is disclosed above, the present utility model is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the utility model, and the scope of the utility model should be assessed accordingly to that of the appended claims.

Finally, it is further noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

In the above embodiments, descriptions of orientations such as "upper", "lower", "inner", "outer", "side", and the like are based on the drawings.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (14)

1. The utility model provides a comdenstion water utilizes device, its characterized in that, including sub-cooling module (100) and heat exchange module (200), sub-cooling module (100) include sub-cooling cavity (110) and be used for the cooling sub-cooling component (120) of sub-cooling cavity (110), heat exchange module (200) include with heat exchange cavity (210) of sub-cooling cavity (110) intercommunication, heat exchange cavity (210) are used for carrying out the heat exchange with article, wherein, water inlet (111) have been seted up to sub-cooling cavity (110), water outlet (211) have been seted up to water inlet (111) be used for with the comdenstion water exit linkage of electrical apparatus, delivery port (211) are used for being connected with water collector (030).

2. The condensate water utilization apparatus of claim 1, wherein the heat exchange module (200) further comprises a heat exchange coil (230), the heat exchange coil (230) being detachably disposed in the heat exchange cavity (210), a first end of the heat exchange coil (230) being configured to receive condensate water cooled by the sub-cooling cavity (110), a second end of the heat exchange coil (230) being connected to the water outlet (211).

3. The condensate water utilizing device of claim 2, wherein the heat exchange module (200) further comprises a coil holder (240), the heat exchange coil (230) is fixedly connected with the coil holder (240), wherein one of a cavity wall of the heat exchange cavity (210) and the coil holder (240) is provided with a clamping groove (212), the other of the cavity wall of the heat exchange cavity (210) and the coil holder (240) is provided with a clamping block (241), and the clamping block (241) is clamped and fixed with the clamping groove (212).

4. The condensate water utilization apparatus of claim 2, wherein a first end of the heat exchange coil (230) is connected to the sub-cooling cavity (110) by a first hose (400), the first end of the heat exchange coil (230) being detachably fixedly connected to the first hose (400); the second end of the heat exchange coil (230) is connected with the water outlet (211) through a second hose (500), and the second end of the heat exchange coil (230) is detachably and fixedly connected with the second hose (500).

5. The condensate water utilization apparatus of claim 2, wherein the heat exchange module (200) further comprises a coil support frame (250), the coil support frame (250) being fixedly disposed in the heat exchange cavity (210), the coil support frame (250) being configured to support the heat exchange coil (230).

6. The condensate water utilizing device according to claim 1, wherein the heat exchange module (200) further comprises a housing (260) and a tray body (220), the housing (260) has a top opening, the tray body (220) is openably and closably covered on the top opening, the tray body (220) is butted with the housing (260) to form the heat exchange cavity (210), wherein the tray body (220) is at least partially arched towards the direction of the heat exchange cavity (210), so that a storage groove (221) is formed on one surface of the tray body (220) facing away from the heat exchange cavity (210).

7. The condensate water utilization device of claim 1, wherein the sub-cooling module (100) further comprises a branching heat exchange structure (130), the branching heat exchange structure (130) being disposed in the sub-cooling cavity (110), an inlet end of the branching heat exchange structure (130) being in communication with the water inlet (111), an outlet end of the branching heat exchange structure (130) being connected to the heat exchange cavity (210).

8. The condensate water utilization apparatus of claim 7, wherein the sub-cooling module (100) further comprises a water pump (140), the water pump (140) is disposed in the sub-cooling cavity (110), a pump inlet of the water pump (140) is connected with the water inlet (111), and a pump outlet of the water pump (140) is connected with an outlet end of the branching heat exchange structure (130).

9. The condensate water utilizing device according to claim 1, wherein at least one cavity wall of the sub-cooling cavity (110) is provided with the sub-cooling element (120), the sub-cooling element (120) comprises a semiconductor refrigerating sheet (121) and a fan (122), the sub-cooling cavity (110) is a closed cavity, the semiconductor refrigerating sheet (121) is fixedly connected with the cavity wall of the sub-cooling cavity (110), wherein the semiconductor refrigerating sheet (121) is used for providing cold for the sub-cooling cavity (110), and the fan (122) is used for blowing heat generated by the semiconductor refrigerating sheet (121) to the external environment.

10. The condensate water utilizing apparatus of claim 9, wherein the sub-cooling module (100) further comprises a mesh enclosure (150), the mesh enclosure (150) being fixedly disposed outside the sub-cooling cavity (110), the mesh enclosure (150) enclosing the semiconductor cooling fin (121) and the blower (122).

11. The condensate water utilization device according to any one of claims 1-10, further comprising a filter module (300), the filter module (300) comprising a filter cavity (310) and a filter cartridge (320), the filter cavity (310) being in communication with the water outlet (211), and the filter cavity (310) being provided with a drain outlet (311), the water outlet (211) being connected with the water collecting device (030) via the drain outlet (311); the filter element (320) is arranged in the filter cavity (310), and the filter element (320) is positioned in a flow path from the water outlet (211) to the water outlet (311).

12. The condensate water utilizing apparatus as claimed in claim 11, wherein a pick-and-place opening is provided in a cavity wall of the filter cavity (310), the pick-and-place opening is provided with an openable baffle (330), and the filter element (320) can be taken out and put in through the pick-and-place opening.

13. The condensate water utilizing device according to claim 11, wherein the filter module (300) further comprises a filter box (340) and a partition plate (350), the partition plate (350) is arranged in the filter box (340), an inner space of the filter box (340) is partitioned into a water diversion cavity (360) and the filter cavity (310) from top to bottom, the water diversion cavity (360) is directly communicated with the water outlet (211), the filter cavity (310) is directly communicated with the water outlet (311), and a plurality of water diversion holes (351) distributed in a dispersed manner are formed in the partition plate (350).

14. An air conditioning system comprising an air conditioner (020), a water collecting device (030) and the condensate water utilizing device according to any one of claims 1 to 13, wherein a water inlet (111) of the condensate water utilizing device is connected to a condensate water outlet of the air conditioner (020), and a water outlet (311) of the condensate water utilizing device is connected to the water collecting device (030).

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