CN215063168U - Water receiving device and heat exchange equipment - Google Patents

Abstract

The utility model provides a water receiving device and indirect heating equipment. Wherein, water receiving device includes: the water receiving tray is provided with a water receiving part and a water discharging part; and the water receiving part is communicated with the flow guide structure through the water discharging part. The utility model discloses a rationally set up the structure of water receiving device for the comdenstion water on the heat exchanger flows to the water receiving portion of water receiving device, collects the back through water receiving portion, by the drainage portion drainage to the water conservancy diversion structure, then flows out indirect heating equipment under the direction of water conservancy diversion structure. The water receiving portion, the drainage portion and the diversion structure are matched with each other to limit the flow path of the condensed water in the heat exchange equipment, so that the collection and the directional discharge of the condensed water are realized, the condensed water is prevented from flowing to other electrified devices or being accumulated in the inside of the heat exchange equipment, the use safety and the use reliability of products are favorably improved, the service life of the products is favorably prolonged, and the maintenance of subsequent products are facilitated.

Description

Water receiving device and heat exchange equipment

Technical Field

The utility model relates to a indirect heating equipment technical field particularly, relates to a water receiving device and indirect heating equipment.

Background

The condensed water drainage mode of the air cooling module machine, the commercial heating unit and the like in the current market is a free drainage mode, namely, the condensed water is not collected and is directly drained into the machine or the ground. There are the following problems: 1. the free drainage structure, inside water will all flow into the machine, rivers were gone up to inside electrical part or the copper pipe that generates heat, caused the damage of device or the fracture of pipeline easily. 2. In the extremely cold and high-humidity area, water flows into the interior of the machine, and is frozen to wrap the internal devices, so that the internal devices are damaged. 3. The interior of the machine is frozen, and the maintenance is seriously influenced.

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 a first aspect provides a water receiving device.

The second aspect of the utility model provides a indirect heating equipment.

In view of this, the utility model discloses a first aspect provides a water receiving device, includes: the water receiving tray is provided with a water receiving part and a water discharging part; and the water receiving part is communicated with the flow guide structure through the water discharging part.

The utility model provides a pair of water collector includes water collector and water conservancy diversion structure, and the water collector has water receiving portion and drainage portion. Wherein, water receiving portion is linked together with water discharge portion, and water discharge portion is linked together with water conservancy diversion structure, that is to say, water receiving portion and water conservancy diversion structure are linked together through water discharge portion.

Specifically, the heat exchange equipment comprises a water receiving device and a heat exchanger, the heat exchanger is located above the water receiving device along the direction from the top to the bottom of the heat exchange equipment, and the heat exchanger is communicated with the water receiving portion of the water receiving device. When the heat exchange equipment works, condensed water on the heat exchanger flows to the water receiving part of the water receiving device, is collected by the water receiving part and then is discharged to the flow guide structure by the water discharging part, and then flows out of the heat exchange equipment under the guide of the flow guide structure. The water receiving portion, the drainage portion and the diversion structure are matched with each other to limit the flow path of the condensed water in the heat exchange equipment, so that the collection and the directional discharge of the condensed water are realized, the condensed water is prevented from flowing to other electrified devices or being accumulated in the inside of the heat exchange equipment, the use safety and the use reliability of products are favorably improved, the service life of the products is favorably prolonged, and the maintenance of subsequent products are facilitated.

This setting has been solved because heat exchange equipment is not provided with the water receiving device among the correlation technique for inside rivers all flowed into heat exchange equipment, and lead to causing the damage of device or the fracture of pipeline easily, influence subsequent maintenance, and the problem of incident easily takes place, has promoted the performance of product.

According to the utility model discloses foretell water receiving device can also have following additional technical characterstic:

in the above technical solution, further, the drainage portion is located on a peripheral side of the water receiving portion.

In this technical scheme, through the cooperation structure of reasonable setting drainage portion and water receiving portion for drainage portion is located the week side of water receiving portion, and that is, the comdenstion water on the heat exchanger flows to water receiving portion, collects the back through water receiving portion, by the week side flow direction drainage portion of water receiving portion. The validity and feasibility of the communication of the water receiving part and the flow guide structure can be guaranteed by the arrangement, and the condensed water collected by the water receiving part can be effectively guided into the flow guide structure.

In any one of the above technical solutions, further, the drainage portion includes a plurality of drainage holes, and the plurality of drainage holes are arranged at intervals along a circumferential direction of the water receiving portion.

In this technical scheme, drainage portion includes a plurality of wash ports, and through the distribution structure who rationally sets up a plurality of wash ports, a plurality of wash ports are arranged along the circumference interval of water receiving portion, should set up the drainage area who has increased drainage portion, have richened drainage portion's drainage angle for water in the water receiving portion can be followed the drainage portion of different positions department and arranged to the guide structure. Simultaneously, this setting can reduce the machining precision requirement of butt joint water tray when guaranteeing the validity of drainage of water drainage portion, promotes the machining efficiency of product, reduces the manufacturing cost of product, that is to say, even because processing error leads to the local convex-concave of water receiving portion uneven, the slope even, also can guarantee the validity of drainage.

In any one of the above technical solutions, further, the water discharge portion includes a plurality of water discharge grooves, and a plurality of water discharge grooves are arranged along the circumference interval of the water receiving portion, and the water discharge grooves are groove structures formed by the edge of the water receiving tray sinking towards the water receiving portion.

In this technical scheme, water drainage portion includes a plurality of water drainage tank, and wherein, water drainage tank is the edge of water collector and caves in the groove structure who forms towards water collection portion. Through the distribution structure who rationally sets up a plurality of water drainage tank, a plurality of water drainage tank are arranged along the circumference interval of water receiving portion, should set up the drainage area who has increased water discharging portion, have richened water discharging portion's drainage angle for water in the water receiving portion can be followed the water discharging portion of different positions department and arranged to the guide structure. Simultaneously, this setting can reduce the machining precision requirement of butt joint water tray when guaranteeing the validity of drainage of water drainage portion, promotes the machining efficiency of product, reduces the manufacturing cost of product, that is to say, even because processing error leads to the local convex-concave of water receiving portion uneven, the slope even, also can guarantee the validity of drainage.

In any one of the above technical solutions, further, the diversion structure is connected with one side of the water receiving tray away from the water receiving portion.

In this technical scheme, through the cooperation structure of reasonable water conservancy diversion structure and water receiving portion that sets up for water conservancy diversion structure is connected with one side that the water collector deviates from water receiving portion, and like this, under the action of gravity, the comdenstion water in the water receiving portion can follow the smooth water conservancy diversion structure that flows to of water drainage portion, avoids the comdenstion water to store up the condition emergence in the water receiving portion, can guarantee the validity and the feasibility of drainage.

Simultaneously, the occupation of the space on the upper part of the drainage tray by the flow guide structure can be reduced, and the condition that the flow guide structure interferes with a heat exchanger of heat exchange equipment is avoided.

In any of the above technical solutions, further, the flow guiding structure includes: the guiding gutter is connected with the water collector, and the notch of guiding gutter deviates from one side of water receiving portion towards the water collector, and the notch of guiding gutter corresponds the setting with water drainage, and wherein, the guiding gutter is provided with the water conservancy diversion mouth.

In this technical scheme, the water conservancy diversion structure includes the guiding gutter, and the guiding gutter is located one side that the water collector deviates from the water receiving portion, and the notch of guiding gutter deviates from one side of water receiving portion towards the water collector, and the notch of guiding gutter corresponds the setting with the drainage portion, and like this, the comdenstion water in the drainage portion can flow to the notch of guiding gutter smoothly, and then flows to the guiding opening under the guide effect of guiding gutter to the guiding gutter of discharging.

It can be understood that one side that guiding gutter and water collector deviate from water receiving portion cooperatees to inject the water conservancy diversion passageway of comdenstion water, should set up the current structure of rational utilization water collector, reduced the material input of water conservancy diversion structure, when guaranteeing validity and the feasibility of water conservancy diversion, reduced the input of material, be favorable to reduction in production cost.

In any of the above technical solutions, further, the flow guiding structure further includes: the guide groove and the water receiving tray are connected through the connecting plate, one end of the connecting plate is connected with the guide groove, and the other end of the connecting plate is connected with the water receiving tray; wherein, a gap is arranged between the notch of the diversion trench and the water pan.

In this technical scheme, water conservancy diversion structure still includes the connecting plate, and the one end of connecting plate is connected with the guiding gutter, and the other end of connecting plate is connected with the water collector, and that is to say, guiding gutter and water collector pass through the connecting plate and connect as a whole to satisfy the user demand of water conservancy diversion.

In addition, a gap is formed between the notch of the diversion trench and the water receiving tray, the existing structure of the water receiving tray is reasonably utilized, the material investment of the diversion structure is reduced, the effectiveness and the feasibility of diversion are guaranteed, meanwhile, the material investment is reduced, and the production cost is favorably reduced.

Specifically, the connecting plate is buckled and is arranged in order to form Z shape, and the one end of connecting plate is connected with the guiding gutter, and the other end of connecting plate is connected with the water collector, and this setting can increase the cooperation area of connecting plate and guiding gutter and water collector, is favorable to strengthening the structural strength that the guiding gutter and water collector were connected to the connecting plate.

It can be understood that the connecting plate is bent and arranged to enhance the structural strength of the connecting plate, so that the overall matching structural strength of the connecting plate, the diversion trench and the water pan can be improved.

In any of the above technical solutions, further, the flow guiding structure further includes: the joint is connected with the diversion port, and at least one part of the joint protrudes out of one side of the diversion trench, which deviates from the water pan.

In this technical scheme, the water conservancy diversion structure is still including connecting, connects and the cooperation structure of water conservancy diversion mouth through reasonable setting for connect and be connected with the water conservancy diversion mouth, and make at least partly protruding one side that stretches out the guiding gutter and deviate from the water collector that connects, connect and play the effect of assembling the comdenstion water.

The condensed water flows along a continuous flow path formed by the inner wall of the joint and then is discharged out of the joint. The continuous flow channel is formed on the inner wall of the joint, and the condensed water flows through the continuous flow channel, so that the deflection of the condensed water is reduced, the flow loss of the condensed water is reduced, more energy is converted into dynamic pressure, and the discharge of the condensed water is accelerated.

In addition, the joint has the function of collecting flow, reduces the frequency of the phenomena of flow separation, vortex and the like of condensed water, is favorable for reducing the operation noise of the product, and improves the service performance of the product.

In any of the above technical solutions, further, the flow guiding structure further includes: and the drain pipe is connected with the part of the joint, which protrudes out of one side of the diversion trench away from the water pan.

In this technical scheme, water conservancy diversion structure still includes the drain pipe, and the drain pipe is connected with the part that the protruding guiding gutter that stretches out of joint deviates from water collector one side, and the comdenstion water that connects the outflow passes through drain pipe discharge indirect heating equipment. This setting has realized the collection and the directional emission to the comdenstion water, avoids the comdenstion water to flow to other electrified devices or store up in the inside condition of indirect heating equipment and takes place, is favorable to promoting security, the reliability that the product used.

The condensed water flows along a continuous flow path formed by the inner wall of the drain pipe and then is discharged out of the drain pipe. The continuous flow channel is formed on the inner wall of the drain pipe, and the condensed water flows through the continuous flow channel, so that the deflection of the condensed water is reduced, the flow loss of the condensed water is reduced, more energy is converted into dynamic pressure, and the discharge of the condensed water is accelerated.

In addition, the drain pipe has the function of collecting flow, so that the frequency of the phenomena of flow separation, flow shedding, vortex and the like of condensed water is reduced, the running noise of the product is favorably reduced, and the service performance of the product is improved.

In any of the above technical solutions, further, the flow guiding structure further includes: the heating part is connected with the diversion trench and used for supplying heat to the diversion trench.

In this technical scheme, the water conservancy diversion structure still includes heating portion to make heating portion be connected with the guiding gutter, utilize heating portion to the guiding gutter heat supply. When indirect heating equipment is in under the extremely cold environment, accessible heating portion supplies heat to the guiding gutter to the comdenstion water of heating the guiding gutter avoids the comdenstion water to freeze and takes place in order to stop up the condition in the guiding gutter, can guarantee that the water conservancy diversion comdenstion water is not subject to the ambient temperature that indirect heating equipment located, can satisfy diversified user demand, and then can promote the adaptability of product use.

Specifically, heating portion is the heating pipe, and the heating pipe is arranged around the guiding gutter, and this setting can realize that heating portion supplies heat to the different positions of guiding gutter to the comdenstion water of guaranteeing different positions department in the guiding gutter can not freeze by everywhere.

In any one of the above technical solutions, further, at least a portion of the heating portion is located between the water pan and the diversion port, and a gap is formed between a portion of the heating portion corresponding to the diversion port and the diversion port.

In this technical scheme, when external environment temperature is lower, the comdenstion water is easily frozen in water conservancy diversion mouth department, so through the cooperation structure of reasonable setting heating portion and water conservancy diversion mouth for at least some of heating portion is located between water collector and the water conservancy diversion mouth, utilizes heating portion to come the comdenstion water heat supply to water conservancy diversion mouth department, takes place in order to avoid the comdenstion water to take place in the icy condition of water conservancy diversion mouth department, can effectively be discharged in order to guarantee the comdenstion water in the guiding gutter.

It can be understood that, the part that heating portion and water conservancy diversion mouth correspond has the clearance between with the water conservancy diversion mouth, and like this, the comdenstion water can flow through the clearance between heating portion and the water conservancy diversion mouth to guarantee that the comdenstion water that flows to water conservancy diversion mouth department all can be heated by heating portion, can effectively avoid the comdenstion water to take place in the condition that water conservancy diversion mouth department freezes.

In any one of the above technical solutions, further, the water receiving device further includes: the support, the water collector is located on the support.

In this technical scheme, water collector still includes the support, and makes the water collector locate on the support, and the support plays the effect of support and fixed to the water collector that is located above that.

Specifically, when the water receiving device is assembled with the heat exchanger of the heat exchange device, the heat exchanger is connected with the support, the support plays a role of bearing the heat exchanger, so that the position relation between the heat exchanger and the water receiving tray is ensured, the position relation between the heat exchanger and the water receiving portion is further ensured, and effective and reliable structural support is provided for the condensate water flowing to the water receiving portion on the heat exchanger.

In any of the above technical solutions, further, a gap is provided between the flow guiding structure and the outer surface of the bracket.

In this technical scheme, have the clearance between the surface of water conservancy diversion structure and support, like this, when avoiding support and water collector assembly, take place to interfere between water conservancy diversion structure and the support and influence the condition emergence of support and water collector assembly, be favorable to reducing the assembly degree of difficulty of water collector and support, promote the assembly efficiency of water collector and support.

In any of the above technical solutions, further, the bracket includes: the frame body is arranged around the periphery of the water receiving tray and connected with the water receiving tray; and the reinforcing structure is connected with the frame body.

In this technical scheme, the support includes framework and additional strengthening. Wherein, the frame encloses the week side of locating the water collector, and the frame is connected with the water collector, should set up with area of contact and the contact angle of increase frame and water collector to support the water collector simultaneously from a plurality of directions and a plurality of angle, in order to guarantee the overall structure intensity of water collector and support.

Further, through setting up additional strengthening for additional strengthening is connected with the framework, utilizes additional strengthening to strengthen the overall structure intensity of support, in order to satisfy the user demand who supports and fix water collector and heat exchanger.

In any of the above technical solutions, further, the reinforcing structure includes: a first reinforcing rib; the second reinforcing ribs are arranged at intervals with the first reinforcing ribs, and any one of the first reinforcing ribs and the second reinforcing ribs is connected with two sides of the frame body; and the third reinforcing rib is positioned between the first reinforcing rib and the second reinforcing rib, one end of the third reinforcing rib is connected with the first reinforcing rib, and the other end of the third reinforcing rib is connected with the second reinforcing rib.

In this technical scheme, the additional strengthening includes first strengthening rib, second strengthening rib and third strengthening rib. Through the cooperation structure of rationally setting up first strengthening rib, second strengthening rib and third strengthening rib for first strengthening rib and second strengthening rib interval arrangement, the third strengthening rib is located between first strengthening rib and the second strengthening rib, and the third strengthening rib all is connected with first strengthening rib and second strengthening rib. This be provided with the area of contact who does benefit to first strengthening rib, second strengthening rib and third strengthening rib of increase, and then can promote the cooperation structural strength of additional strengthening and framework.

Specifically, the first reinforcing rib, the second reinforcing rib and the third reinforcing rib enclose an I shape.

In any of the above technical solutions, further, in the direction from the drainage portion to the diversion port, the distance from the notch of the diversion trench to the bottom of the diversion trench gradually increases.

In this technical scheme, through the structure of reasonable setting guiding gutter for along the direction of water drainage to water conservancy diversion mouth, the distance of the tank bottom of notch to the guiding gutter of guiding gutter crescent. The tank bottom of the diversion trench is obliquely arranged, so that condensed water can flow out conveniently, and the condition of accumulated water in the diversion trench is avoided.

In any of the above technical solutions, further, the water pan has a plurality of corners, the number of the flow guide structures is multiple, and one flow guide structure is arranged at each corner; wherein, the flow guide structure is L-shaped.

In this technical scheme, through the cooperation structure of reasonable water collector and water conservancy diversion structure that sets up for the water collector has a plurality of turnings, and the quantity of water conservancy diversion structure is a plurality of, and every corner is provided with a water conservancy diversion structure, and the water conservancy diversion structure is L shape. The arrangement increases the matching area and the matching angle of the diversion structure and the water receiving tray, so that condensed water discharged from different positions of the water receiving tray can be effectively guided by the diversion structure.

Specifically, the number of corners of the water pan and the number of the flow guide structures are four.

The second aspect of the utility model provides a indirect heating equipment, include: any one technical scheme's in the first aspect water collector.

The utility model provides a heat exchange equipment, because of including as in the first aspect arbitrary technical scheme's water receiving device, consequently, have above-mentioned water receiving device's whole beneficial effect, do not state one by one here.

In the above technical solution, further, the heat exchange device further includes: and the heat exchanger is connected with the water receiving device, and the water receiving part of the water receiving tray is communicated with the heat exchanger.

In this technical scheme, indirect heating equipment still includes the heat exchanger, and the water receiving portion of water collector is linked together with the heat exchanger, and indirect heating equipment during operation, the comdenstion water on the heat exchanger can flow to the water receiving portion, collects the back through the water receiving portion, by the drainage component drainage to the water conservancy diversion structure, then under the direction of water conservancy diversion structure outflow indirect heating equipment.

In any of the above technical solutions, further, the heat exchange device further includes: the stand is connected with the one side that the water receiving device deviates from the heat exchanger.

In this technical scheme, indirect heating equipment still includes the stand, and the stand is connected with the one side that the water receiving device deviates from the heat exchanger, and the stand has the effect of supporting and fixed water receiving device to the assurance is located and has one section distance between heat exchanger and the ground.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, 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 is a partial schematic structural view of a water receiving device according to an embodiment of the present invention;

FIG. 2 is an exploded view of the water collector of FIG. 1;

FIG. 3 is an enlarged view of a portion of FIG. 2;

fig. 4 is a partial schematic structural view of a water receiving device according to another embodiment of the present invention;

FIG. 5 is an exploded view of the water collector of FIG. 4;

FIG. 6 is a partial enlarged view of FIG. 5 at B;

fig. 7 is a schematic structural view illustrating a water receiving device and a heat exchanging portion according to an embodiment of the present invention;

fig. 8 shows a schematic structural diagram of a heat exchange device according to an embodiment of the present invention.

Wherein, the correspondence between the reference numbers and the component names in fig. 1 to 8 is:

100 water receiving devices, 110 water receiving trays, 112 water receiving parts, 114 water discharging parts, 120 flow guide structures, 122 flow guide grooves, 124 flow guide openings, 126 connecting plates, 128 joints, 130 water discharging pipes, 140 supports, 142 frame bodies, 144 reinforcing structures, 146 first reinforcing ribs, 148 second reinforcing ribs, 150 third reinforcing ribs, 200 heat exchange equipment, 210 heat exchangers and 212 heat exchange parts.

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.

With reference to fig. 1 to 8, a water receiving device 100 and a heat exchange device 200 according to some embodiments of the present invention will be described.

Example 1:

as shown in fig. 1, fig. 2, fig. 4, fig. 5, and fig. 7, an embodiment of the first aspect of the present invention provides a water receiving device 100 including a water receiving tray 110 and a diversion structure 120.

The water tray 110 includes a water receiving portion 112 and a drain portion 114.

The diversion structure 120 is connected with the water receiving tray 110, and the water receiving part 112 is communicated with the diversion structure 120 through the drainage part 114.

In detail, the water receiving device 100 includes a water receiving tray 110 and a diversion structure 120, and the water receiving tray 110 has a water receiving portion 112 and a drain portion 114. The water receiving portion 112 is communicated with the water discharging portion 114, and the water discharging portion 114 is communicated with the diversion structure 120, that is, the water receiving portion 112 is communicated with the diversion structure 120 through the water discharging portion 114.

Specifically, as shown in fig. 7, the heat exchanging device 200 includes the water receiving device 100 and a heat exchanger 210, the heat exchanger 210 includes a heat exchanging portion 212, the heat exchanger 210 is located above the water receiving device 100 along a top-to-bottom direction of the heat exchanging device 200, and the heat exchanging portion 212 of the heat exchanger 210 is communicated with the water receiving portion 112 of the water receiving device 100. When the heat exchange device 200 is in operation, condensed water on the heat exchanger 210 flows to the water receiving portion 112 of the water receiving device 100, is collected by the water receiving portion 112, is discharged to the flow guide structure 120 by the water discharge portion 114, and then flows out of the heat exchange device 200 under the guide of the flow guide structure 120. The water receiving portion 112, the drainage portion 114 and the flow guide structure 120 are matched to limit a flow path of the condensed water in the heat exchange device 200, so that the condensed water is collected and directionally discharged, the condensed water is prevented from flowing to other electrified devices or being accumulated in the heat exchange device 200, the use safety and reliability of products are improved, the service life of the products is prolonged, and the maintenance of subsequent products are facilitated.

This setting has been solved because heat exchange equipment is not provided with the water receiving device among the correlation technique for inside rivers all flowed into heat exchange equipment, and lead to causing the damage of device or the fracture of pipeline easily, influence subsequent maintenance, and the problem of incident easily takes place, has promoted the performance of product.

Example 2:

as shown in fig. 1, 2, 4, 5, and 7, based on embodiment 1, embodiment 2 provides a water receiving device 100 that includes a water receiving tray 110 and a diversion structure 120.

The water tray 110 includes a water receiving portion 112 and a drain portion 114.

The diversion structure 120 is connected with the water receiving tray 110, and the water receiving part 112 is communicated with the diversion structure 120 through the drainage part 114.

Further, as shown in fig. 2, 5, and 7, the drain portion 114 is located on the peripheral side of the water receiving portion 112.

In detail, by properly arranging the matching structure of the water draining portion 114 and the water receiving portion 112, the water draining portion 114 is located on the peripheral side of the water receiving portion 112, that is, the condensed water on the heat exchanger 210 flows to the water receiving portion 112, and after being collected by the water receiving portion 112, flows to the water draining portion 114 from the peripheral side of the water receiving portion 112. The arrangement can ensure the effectiveness and feasibility of the communication between the water receiving portion 112 and the flow guide structure 120, and ensure that the condensed water collected by the water receiving portion 112 can be effectively guided into the flow guide structure 120.

Further, as shown in fig. 2, 5, and 7, the drain portion 114 includes a plurality of drain holes arranged at intervals along the circumferential direction of the water receiving portion 112.

Wherein, drainage portion 114 includes a plurality of wash ports, and through the distribution structure who rationally sets up a plurality of wash ports, a plurality of wash ports are arranged along water receiving portion 112's circumference interval, and this setting has increased drainage area of drainage portion 114, has richened drainage portion 114's drainage angle for water in the water receiving portion 112 can arrange to flow structure 120 from drainage portion 114 of different positions department. Meanwhile, the arrangement can reduce the requirement on the processing precision of the water tray 110, improve the processing efficiency of products and reduce the production cost of the products while ensuring the effectiveness of the drainage part 114, namely, even if the water receiving part 112 is locally uneven or even inclined due to processing errors, the effectiveness of the drainage can be ensured.

Specifically, the outline of the drainage hole in the cross section is elliptical, triangular, rectangular, pentagonal, or irregular, and the like, which are not listed here. Wherein, the irregular shape refers to a structure with irregular shape.

Specifically, the plurality of drain holes are identical in shape.

Alternatively, some of the plurality of drain holes may have the same shape, and the other drain holes may have different shapes.

Alternatively, any two of the plurality of drain holes may have different shapes.

Further, as shown in fig. 1, 2 and 5, the water pan 110 has a plurality of corners, and the number of the flow guiding structures 120 is plural, and one flow guiding structure 120 is disposed at each corner; wherein, the flow guiding structure 120 is L-shaped.

Wherein, through the cooperation structure of reasonable setting water collector 110 and water conservancy diversion structure 120 for water collector 110 has a plurality of turnings, and the quantity of water conservancy diversion structure 120 is a plurality of, and every corner is provided with a water conservancy diversion structure 120, and water conservancy diversion structure 120 is L shape. The arrangement increases the matching area and the matching angle between the diversion structure 120 and the water-receiving tray 110, so that the condensed water discharged from different positions of the water-receiving tray 110 can be effectively guided by the diversion structure 120.

Specifically, the number of corners of the water collector 110 and the number of the flow guide structures 120 are four.

Example 3:

as shown in fig. 1, 2, 4, 5, and 7, based on embodiment 1 or embodiment 2, embodiment 3 provides a water receiving device 100 including a water receiving tray 110 and a diversion structure 120.

The water tray 110 includes a water receiving portion 112 and a drain portion 114.

The diversion structure 120 is connected with the water receiving tray 110, and the water receiving part 112 is communicated with the diversion structure 120 through the drainage part 114.

Further, the drain portion 114 includes a plurality of drain grooves that are arranged at intervals along the circumferential direction of the water receiving portion 112, and the drain grooves are groove structures formed by the edge of the water receiving tray 110 being recessed toward the water receiving portion 112.

In detail, the drain part 114 includes a plurality of drain grooves, wherein the drain grooves are a groove structure formed by the edge of the water-receiving tray 110 being recessed toward the water-receiving part 112. Through the distribution structure of rationally setting up a plurality of water drainage tank, a plurality of water drainage tank are arranged along the circumference interval of water receiving portion 112, and this setting has increased the drainage area of water discharging portion 114, has richened water discharging portion 114's drainage angle for water in the water receiving portion 112 can discharge to flow structure 120 from water discharging portion 114 of different positions. Meanwhile, the arrangement can reduce the requirement on the processing precision of the water tray 110, improve the processing efficiency of products and reduce the production cost of the products while ensuring the effectiveness of the drainage part 114, namely, even if the water receiving part 112 is locally uneven or even inclined due to processing errors, the effectiveness of the drainage can be ensured.

Specifically, the plurality of drain grooves are identical in shape.

Alternatively, some of the plurality of drainage grooves may have the same shape, and the other drainage grooves may have different shapes.

Alternatively, any two of the plurality of drain grooves may have different shapes.

Example 4:

as shown in fig. 1, 2, 4, 5, and 7, in addition to any of the above embodiments, embodiment 4 provides a water receiving device 100 that includes a water receiving tray 110 and a diversion structure 120.

The water tray 110 includes a water receiving portion 112 and a drain portion 114.

The diversion structure 120 is connected with the water receiving tray 110, and the water receiving part 112 is communicated with the diversion structure 120 through the drainage part 114.

Further, the diversion structure 120 is connected to a side of the water receiving tray 110 away from the water receiving portion 112.

In detail, through the cooperation structure of rationally setting flow guide structure 120 and water receiving portion 112 for flow guide structure 120 is connected with one side that water receiving tray 110 deviates from water receiving portion 112, and like this, under the action of gravity, the comdenstion water in the water receiving portion 112 can follow drainage portion 114 and flow to flow guide structure 120 smoothly, avoids the comdenstion water to store up the condition emergence in the water receiving portion 112, can guarantee the validity and the feasibility of drainage.

Meanwhile, the arrangement can reduce the occupation of the flow guide structure 120 on the upper space of the drain pan, and avoid the occurrence of the interference between the flow guide structure 120 and the heat exchanger 210 of the heat exchange device 200.

Further, as shown in fig. 1, 2, 4 and 5, the diversion structure 120 includes a diversion trench 122, and the diversion trench 122 is connected to the water collector 110.

The notch of the diversion trench 122 faces the side of the water receiving tray 110 departing from the water receiving portion 112, the notch of the diversion trench 122 corresponds to the drainage portion 114, and the diversion trench 122 is provided with a diversion port 124.

Wherein, water conservancy diversion structure 120 includes guiding gutter 122, guiding gutter 122 is located the one side that the water collector 110 deviates from water receiving portion 112, the notch of guiding gutter 122 is towards the one side that the water collector 110 deviates from water receiving portion 112, and the notch of guiding gutter 122 corresponds the setting with water drainage 114, and like this, the interior condensate water of water drainage 114 can flow to the notch of guiding gutter 122 smoothly, and then flows to guiding opening 124 under the guide effect of guiding gutter 122 to discharge guiding gutter 122.

It can be understood that the diversion trench 122 and one side of the water receiving tray 110 departing from the water receiving part 112 are matched to define a diversion channel of condensed water, the existing structure of the water receiving tray 110 is reasonably utilized by the arrangement, the material investment of the diversion structure 120 is reduced, the material investment is reduced while the effectiveness and feasibility of diversion are ensured, and the production cost is favorably reduced.

Further, in the direction from the drain portion 114 to the diversion opening 124, the distance from the opening of the diversion trench 122 to the bottom of the diversion trench 122 gradually increases.

Wherein, through the structure of reasonable setting of guiding gutter 122 for along the direction of drain 114 to water conservancy diversion mouth 124, the distance of the tank bottom of guiding gutter 122 to guiding gutter 122 is crescent. That is, the bottom of the diversion trench 122 is inclined, so that the condensed water can flow out conveniently, and the condition of water accumulation in the diversion trench 122 is avoided.

Example 5:

as shown in fig. 1, 2, 4, 5, and 7, based on embodiment 4, embodiment 5 provides a water receiving device 100 that includes a water receiving tray 110 and a diversion structure 120.

The water tray 110 includes a water receiving portion 112 and a drain portion 114.

The diversion structure 120 is connected with the water receiving tray 110, and the water receiving part 112 is communicated with the diversion structure 120 through the drainage part 114.

The diversion structure 120 is connected to a side of the water receiving tray 110 away from the water receiving portion 112.

The diversion structure 120 includes a diversion trench 122, and the diversion trench 122 is connected to the water collector 110.

The notch of the diversion trench 122 faces the side of the water receiving tray 110 departing from the water receiving portion 112, the notch of the diversion trench 122 corresponds to the drainage portion 114, and the diversion trench 122 is provided with a diversion port 124.

Further, as shown in fig. 1, 3, 4 and 6, the diversion structure 120 further includes a connection plate 126, and the diversion trench 122 and the water pan 110 are connected by the connection plate 126.

One end of the connecting plate 126 is connected to the diversion trench 122, and the other end of the connecting plate 126 is connected to the water pan 110.

A gap is formed between the notch of the baffle groove 122 and the water pan 110.

The diversion structure 120 further includes a connecting plate 126, one end of the connecting plate 126 is connected to the diversion trench 122, and the other end of the connecting plate 126 is connected to the water pan 110, that is, the diversion trench 122 and the water pan 110 are connected to form a whole through the connecting plate 126, so as to meet the use requirement of diversion.

In addition, a gap is formed between the notch of the diversion trench 122 and the water receiving tray 110, the existing structure of the water receiving tray 110 is reasonably utilized, the material investment of the diversion structure 120 is reduced, the effectiveness and the feasibility of diversion are guaranteed, meanwhile, the material investment is reduced, and the production cost is favorably reduced.

Specifically, the connecting plate 126 is bent to form a Z shape, one end of the connecting plate 126 is connected with the diversion trench 122, and the other end of the connecting plate 126 is connected with the water collector 110, so that the matching area of the connecting plate 126 with the diversion trench 122 and the water collector 110 can be increased, and the structural strength of the connecting plate 126 for connecting the diversion trench 122 with the water collector 110 can be enhanced.

It will be appreciated that the bent arrangement of the connection plate 126 may enhance the structural strength of the connection plate 126, which may be beneficial to enhance the overall mating structural strength of the connection plate 126, the baffle 122 and the drip tray 110.

Example 6:

as shown in fig. 1, 2, 4, 5, and 7, based on embodiment 4 or 5, embodiment 6 provides a water receiving device 100 including a water receiving tray 110 and a diversion structure 120.

The water tray 110 includes a water receiving portion 112 and a drain portion 114.

The diversion structure 120 is connected with the water receiving tray 110, and the water receiving part 112 is communicated with the diversion structure 120 through the drainage part 114.

The diversion structure 120 is connected to a side of the water receiving tray 110 away from the water receiving portion 112.

The diversion structure 120 includes a diversion trench 122, and the diversion trench 122 is connected to the water collector 110.

The notch of the diversion trench 122 faces the side of the water receiving tray 110 departing from the water receiving portion 112, the notch of the diversion trench 122 corresponds to the drainage portion 114, and the diversion trench 122 is provided with a diversion port 124.

Further, as shown in fig. 1, 3, 4 and 6, the diversion structure 120 further includes a joint 128, and the joint 128 is connected to the diversion port 124.

And at least a portion of the fitting 128 projects out of the side of the channel 122 facing away from the drip tray 110.

The diversion structure 120 further includes a joint 128, and by reasonably setting a matching structure of the joint 128 and the diversion opening 124, the joint 128 is connected to the diversion opening 124, and at least a part of the joint 128 protrudes out of one side of the diversion trench 122 away from the water-receiving tray 110, so that the joint 128 plays a role in gathering condensed water.

The condensate flows along a continuous flow path formed by the inner walls of the fitting 128 and then exits the fitting 128. The continuous flow channel formed by the inner wall of the joint 128 allows the condensed water to flow through the continuous flow channel, so that the deflection of the condensed water is reduced, the flow loss of the condensed water is reduced, more energy is converted into dynamic pressure, and the discharge of the condensed water is accelerated.

In addition, the joint 128 has a flow collecting function, so that the frequency of phenomena of flow separation, flow shedding, vortex and the like of condensed water is reduced, the operation noise of a product is reduced, and the use performance of the product is improved.

Further, as shown in fig. 7 and 8, the flow guiding structure 120 further includes: and the drain pipe 130 is connected with the part of the joint, which protrudes out of the diversion channel 122 and faces away from one side of the water pan 110.

The diversion structure 120 further includes a drain pipe 130, the drain pipe 130 is connected to a portion of the joint protruding out of one side of the diversion trench 122 away from the water pan 110, and the condensed water flowing out of the joint 128 is discharged out of the heat exchange device 200 through the drain pipe 130. This setting has realized the collection and the directional emission to the comdenstion water, avoids the comdenstion water to flow to other electrified devices or store up in the inside condition emergence of indirect heating equipment 200, is favorable to promoting security, the reliability that the product used.

The condensed water flows along a continuous flow path formed by the inner wall of the drain pipe 130 and then is discharged out of the drain pipe 130. The continuous flow channel formed on the inner wall of the drain pipe 130 allows the condensed water to flow through the continuous flow channel, thereby reducing the deflection of the condensed water, reducing the flow loss of the condensed water, converting more energy into dynamic pressure, and accelerating the discharge of the condensed water.

In addition, the drain pipe 130 has a flow-collecting function, so that the frequency of the phenomena of flow separation, flow shedding, vortex and the like of condensed water is reduced, the operation noise of the product is reduced, and the use performance of the product is improved.

Specifically, the drain pipe 130 is a metal pipe or a plastic pipe.

Alternatively, the drain pipe 130 is a rubber pipe.

Example 7:

as shown in fig. 1, 2, 4, 5, and 7, on the basis of any one of embodiments 4 to 6, embodiment 7 provides a water receiving device 100 including a water receiving tray 110 and a diversion structure 120.

The water tray 110 includes a water receiving portion 112 and a drain portion 114.

The diversion structure 120 is connected with the water receiving tray 110, and the water receiving part 112 is communicated with the diversion structure 120 through the drainage part 114.

The diversion structure 120 is connected to a side of the water receiving tray 110 away from the water receiving portion 112.

The diversion structure 120 includes a diversion trench 122, and the diversion trench 122 is connected to the water collector 110.

The notch of the diversion trench 122 faces the side of the water receiving tray 110 departing from the water receiving portion 112, the notch of the diversion trench 122 corresponds to the drainage portion 114, and the diversion trench 122 is provided with a diversion port 124.

Further, the diversion structure 120 further includes a heating portion, the heating portion is connected to the diversion trench 122, and the heating portion is used for supplying heat to the diversion trench 122.

In detail, the diversion structure 120 further includes a heating portion, and the heating portion is connected to the diversion trench 122, and the heating portion supplies heat to the diversion trench 122. When indirect heating equipment 200 is in extremely cold environment, accessible heating portion supplies heat to guiding gutter 122 to the comdenstion water in the heating guiding gutter 122 avoids the comdenstion water to freeze and takes place with the condition of blockking up in guiding gutter 122, can guarantee that the water conservancy diversion comdenstion water is not subject to the ambient temperature that indirect heating equipment 200 located, can satisfy diversified user demand, and then can promote the adaptability of product use.

Specifically, the heating portion is a heating pipe, the heating pipe is arranged around the diversion trench 122, and the heating portion can be arranged to supply heat to different positions of the diversion trench 122, so that the condensate water at different positions in the diversion trench 122 can not be frozen.

Further, at least a part of the heating portion is located between the water collector 110 and the diversion opening 124, and a gap is formed between the part of the heating portion corresponding to the diversion opening 124 and the diversion opening 124.

When the external environment temperature is low, the condensate water is easy to freeze at the diversion opening 124, so that at least one part of the heating part is located between the water pan 110 and the diversion opening 124 by reasonably arranging the matching structure of the heating part and the diversion opening 124, and the heating part is utilized to supply heat to the condensate water at the diversion opening 124, so as to avoid the condition that the condensate water freezes at the diversion opening 124, and ensure that the condensate water in the diversion trench 122 can be effectively discharged.

It can be understood that a gap is formed between the portion of the heating portion corresponding to the diversion opening 124 and the diversion opening 124, so that the condensed water can flow through the gap between the heating portion and the diversion opening 124, and the condensed water flowing to the diversion opening 124 can be heated by the heating portion, thereby effectively preventing the condensed water from freezing at the diversion opening 124.

Example 8:

as shown in fig. 1, 2, 4, 5, and 7, in addition to any of the above embodiments, embodiment 8 provides a water receiving device 100 that includes a water receiving tray 110 and a diversion structure 120.

The water tray 110 includes a water receiving portion 112 and a drain portion 114.

The diversion structure 120 is connected with the water receiving tray 110, and the water receiving part 112 is communicated with the diversion structure 120 through the drainage part 114.

Further, as shown in fig. 4 and 5, the water receiving device 100 further includes a bracket 140, and the water receiving tray 110 is disposed on the bracket 140.

In detail, the water collector 100 further includes a bracket 140, and the water collector 110 is disposed on the bracket 140, and the bracket 140 supports and fixes the water collector 110 thereon.

Specifically, when the water receiving device 100 is assembled with the heat exchanger 210 of the heat exchange apparatus 200, the heat exchanger 210 is connected to the bracket 140, and the bracket 140 plays a role of bearing the heat exchanger 210, so as to ensure the position relationship between the heat exchanger 210 and the water receiving tray 110, further ensure the position relationship between the heat exchanger 210 and the water receiving portion 112, and provide effective and reliable structural support for the condensed water on the heat exchanger 210 to flow to the water receiving portion 112.

Specifically, the bracket 140 is detachably connected to the water tray 110. The bracket 140 is connected with the water pan 110 in any one or combination of the following ways: clamping, screwing, magnetic attraction and fastening connection through a fastener (such as a screw, a bolt or a rivet).

It can be understood that the bracket 140 is detachably connected to the water-receiving tray 110, that is, the bracket 140 and the water-receiving tray 110 can be disassembled and assembled and the installation position of the water-receiving tray 110 relative to the bracket 140 can be determined according to actual conditions, so that the water-receiving tray is applicable to the use requirements of heat exchange devices 200 of different models, the adaptability of the product is strong, and the use performance of the product is improved.

In other embodiments, the bracket 140 is integrally connected to the water-receiving tray 110, and this structure simplifies the assembly and subsequent disassembly processes of the bracket 140 and the water-receiving tray 110 because the assembly process of the bracket 140 and the water-receiving tray 110 is omitted, which is beneficial to improving the assembly and disassembly efficiency, and further reduces the production and maintenance costs. In addition, the bracket 140 is integrally connected with the water-receiving tray 110, so that the dimensional accuracy requirement of the forming of the water-receiving device 100 can be ensured.

Further, there is a gap between the flow guide structure 120 and the outer surface of the bracket 140.

The gap is formed between the flow guide structure 120 and the outer surface of the support 140, so that when the support 140 and the water-receiving tray 110 are assembled, interference between the flow guide structure 120 and the support 140 is avoided, the assembly of the support 140 and the water-receiving tray 110 is affected, the assembly difficulty of the water-receiving tray 110 and the support 140 is reduced, and the assembly efficiency of the water-receiving tray 110 and the support 140 is improved.

Further, as shown in fig. 5, the bracket 140 includes a frame 142 and a reinforcing structure 144. The frame 142 surrounds the periphery of the water receiving tray 110, the frame 142 is connected to the water receiving tray 110, and the reinforcing structure 144 is connected to the frame 142.

Among other things, the bracket 140 includes a frame 142 and a reinforcing structure 144. The frame 142 surrounds the periphery of the water-receiving tray 110, and the frame 142 is connected to the water-receiving tray 110, so as to increase the contact area and the contact angle between the frame 142 and the water-receiving tray 110, and to support the water-receiving tray 110 from multiple directions and multiple angles, thereby ensuring the strength of the whole structure of the water-receiving tray 110 and the bracket 140.

In addition, by arranging the reinforcing structure 144, the reinforcing structure 144 is connected with the frame 142, and the reinforcing structure 144 is utilized to enhance the overall structural strength of the bracket 140, so as to meet the use requirements of supporting and fixing the water-receiving tray 110 and the heat exchanger 210.

Further, as shown in fig. 5, the reinforcing structure 144 includes a first reinforcing rib 146, a second reinforcing rib 148 and a third reinforcing rib 150, the second reinforcing rib 148 and the first reinforcing rib 146 are arranged at an interval, and any one of the first reinforcing rib 146 and the second reinforcing rib 148 is connected to both sides of the frame 142. The third reinforcing bead 150 is positioned between the first reinforcing bead 146 and the second reinforcing bead 148, one end of the third reinforcing bead 150 is connected to the first reinforcing bead 146, and the other end of the third reinforcing bead 150 is connected to the second reinforcing bead 148.

The reinforcing structure 144 includes, among other things, a first reinforcing bead 146, a second reinforcing bead 148, and a third reinforcing bead 150. Through the cooperation structure of rationally setting up first strengthening rib 146, second strengthening rib 148 and third strengthening rib 150 for first strengthening rib 146 and second strengthening rib 148 interval arrangement, third strengthening rib 150 is located between first strengthening rib 146 and the second strengthening rib 148, and third strengthening rib 150 all is connected with first strengthening rib 146 and second strengthening rib 148. The arrangement is beneficial to increasing the contact area of the first reinforcing rib 146, the second reinforcing rib 148 and the third reinforcing rib 150, so that the matching structural strength of the reinforcing structure 144 and the frame body 142 can be improved.

Specifically, the first reinforcing rib 146, the second reinforcing rib 148 and the third reinforcing rib 150 enclose an "i" shape.

Example 9:

as shown in fig. 8, an embodiment of the second aspect of the present invention provides a heat exchange device 200, including: the water receiving device 100 of any embodiment of the first aspect.

The utility model provides a indirect heating equipment 200 includes water collector 100 and heat exchanger 210, and heat exchanger 210 includes heat exchange portion 212, along indirect heating equipment 200's top to the direction of bottom, and heat exchanger 210 is located water collector 100's top, and heat exchange portion 212 of heat exchanger 210 is linked together with water collector 100's water collector 112.

The water collector 100 includes a water collector 110 and a diversion structure 120, and the water collector 110 has a water collecting part 112 and a water discharging part 114. The water receiving portion 112 is communicated with the water discharging portion 114, and the water discharging portion 114 is communicated with the diversion structure 120, that is, the water receiving portion 112 is communicated with the diversion structure 120 through the water discharging portion 114.

When the heat exchange device 200 is in operation, condensed water on the heat exchanger 210 flows to the water receiving portion 112 of the water receiving device 100, is collected by the water receiving portion 112, is discharged to the flow guide structure 120 by the water discharge portion 114, and then flows out of the heat exchange device 200 under the guide of the flow guide structure 120. The water receiving portion 112, the drainage portion 114 and the flow guide structure 120 are matched to limit a flow path of the condensed water in the heat exchange device 200, so that the condensed water is collected and directionally discharged, the condensed water is prevented from flowing to other electrified devices or being accumulated in the heat exchange device 200, the use safety and reliability of products are improved, the service life of the products is prolonged, and the maintenance of subsequent products are facilitated.

This setting has been solved because heat exchange equipment is not provided with the water receiving device among the correlation technique for inside rivers all flowed into heat exchange equipment, and lead to causing the damage of device or the fracture of pipeline easily, influence subsequent maintenance, and the problem of incident easily takes place, has promoted the performance of product.

Further, as shown in fig. 8, the heat exchanging apparatus 200 further includes a heat exchanger 210, the heat exchanger 210 is connected to the water receiving device 100, and the water receiving portion 112 of the water receiving tray 110 is communicated with the heat exchanger 210.

The heat exchange device 200 further comprises a heat exchanger 210, the water receiving portion 112 of the water receiving tray 110 is communicated with the heat exchanger 210, when the heat exchange device 200 works, condensed water on the heat exchanger 210 flows to the water receiving portion 112, is collected by the water receiving portion 112, is discharged to the flow guide structure 120 through the water discharge portion 114, and then flows out of the heat exchange device 200 under the guide of the flow guide structure 120.

Further, the heat exchanging device 200 further includes a vertical column, and the vertical column is connected to a side of the water receiving device 100 away from the heat exchanger 210.

The heat exchange device 200 further includes a vertical column, the vertical column is connected to a side of the water receiving device 100 away from the heat exchanger 210, and the vertical column has a function of supporting and fixing the water receiving device 100, so as to ensure that a distance is formed between the heat exchanger 210 and the ground.

Specifically, the heat exchange equipment includes: air-cooled modular units, heating units, etc., not to name a few.

Example 10:

as shown in fig. 4 and 5, the heat exchange device 200 includes: a heat exchanger 210, a water pan 110, a flow guide structure 120 and a bracket 140.

The water receiving tray 110 includes a water receiving portion 112 and a drain portion 114, the water receiving portion 112 communicates with the drain portion 114, and the drain portion 114 includes a plurality of drain holes.

The diversion structure 120 is designed below the water-receiving tray 110 (the diversion structure 120 comprises a diversion groove 122), the diversion groove 122 is not contacted with the bracket 140, and the diversion groove 122 is assembled with the water-receiving tray 110 through screws or welding.

At least one diversion opening 124 is disposed within diversion trench 122.

The diversion structure 120 further includes a connector 128 and a drain 130, the connector 128 is connected to the diversion port 124, and the drain 130 is connected to the connector 128.

Heating portion (heating portion includes the heating pipe), and the heating pipe sets up in guiding gutter 122, and at least a part of heating portion is located between water collector 110 and guiding opening 124, and has the clearance between the part that heating portion and guiding opening 124 correspond and guiding opening 124.

The condensed water flowing out of the heat exchanger 210 (for example, the heat exchanger 210 is a condenser) flows through the water receiving tray 110, rapidly flows out through the drain hole, is collected by the diversion trench 122, sequentially passes through the diversion port 124, the joint 128 and the drain pipe 130, is guided out of the heat exchange device 200, is not frozen and accumulated inside the heat exchange device 200, and achieves the purpose of concentrated discharge of the condensed water.

Example 11:

as shown in fig. 1 and 2, the heat exchanging apparatus 200 includes a heat exchanger 210, a water receiving tray 110, and a flow guiding structure 120.

The water receiving tray 110 includes a water receiving portion 112 and a drain portion 114, the water receiving portion 112 communicates with the drain portion 114, and the drain portion 114 includes a plurality of drain holes.

A flow guide structure 120 is designed below the water-receiving tray 110 (the flow guide structure 120 comprises a flow guide groove 122), and the flow guide groove 122 is assembled with the water-receiving tray 110 through screws or welding.

At least one diversion opening 124 is disposed within diversion trench 122.

The diversion structure 120 further includes a connector 128 and a drain 130, the connector 128 is connected to the diversion port 124, and the drain 130 is connected to the connector 128.

Heating portion (heating portion includes the heating pipe), and the heating pipe sets up in guiding gutter 122, and at least a part of heating portion is located between water collector 110 and guiding opening 124, and has the clearance between the part that heating portion and guiding opening 124 correspond and guiding opening 124.

The condensed water flowing out of the heat exchanger 210 (for example, the heat exchanger 210 is a condenser) flows through the water receiving tray 110, rapidly flows out through the drain hole, is collected by the diversion trench 122, sequentially passes through the diversion port 124, the joint 128 and the drain pipe 130, is guided out of the heat exchange device 200, is not frozen and accumulated inside the heat exchange device 200, and achieves the purpose of concentrated discharge of the condensed water.

In the present application, the term "plurality" means two or more unless expressly defined otherwise. The terms "mounted," "connected," "fixed," and the like are to be construed broadly, and for example, "connected" may be a fixed connection, a removable connection, or an integral connection; "coupled" may be direct or indirect through an intermediary. 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 (18)

1. A water receiving device, its characterized in that includes:

the water receiving tray is provided with a water receiving part and a water discharging part;

and the water receiving part is communicated with the flow guide structure through the drainage part.

2. A water receiving device as claimed in claim 1,

the drainage part is located on the periphery side of the water receiving part.

3. A water receiving device as claimed in claim 2,

the drainage part comprises a plurality of drainage holes which are arranged at intervals along the circumferential direction of the water receiving part; and/or

The water draining part comprises a plurality of water draining grooves, the water draining grooves are arranged along the circumferential direction of the water receiving part at intervals, and the water draining grooves are of groove structures formed by the water receiving part in a concave mode, and the edges of the water receiving tray face the water receiving part.

4. A water receiving device according to any one of claims 1-3,

the water diversion structure is connected with one side of the water receiving plate, which deviates from the water receiving part.

5. A water receiving device as claimed in claim 4, wherein the flow directing arrangement comprises:

a diversion trench connected with the water receiving tray, wherein the notch of the diversion trench faces to one side of the water receiving tray departing from the water receiving part and is arranged corresponding to the drainage part,

wherein, the diversion trench is provided with a diversion port.

6. A water receiving device as claimed in claim 5, wherein the flow directing arrangement further comprises:

the guide groove and the water receiving tray are connected through the connecting plate, one end of the connecting plate is connected with the guide groove, and the other end of the connecting plate is connected with the water receiving tray;

wherein, a gap is arranged between the notch of the diversion trench and the water pan.

7. A water receiving device as claimed in claim 5, wherein the flow directing arrangement further comprises:

the joint is connected with the flow guide port, and at least one part of the joint protrudes out of one side of the flow guide groove, which deviates from the water receiving disc.

8. A water receiving device as claimed in claim 7, wherein the flow directing arrangement further comprises:

and the drain pipe is connected with the part of the joint, which protrudes out of one side of the diversion trench, which deviates from the water pan.

9. A water receiving device as claimed in claim 5, wherein the flow directing arrangement further comprises:

the heating part is connected with the diversion trench and used for supplying heat to the diversion trench.

10. A water receiving device as claimed in claim 9,

at least one part of the heating part is positioned between the water receiving tray and the flow guide opening, and a gap is formed between the part of the heating part corresponding to the flow guide opening and the flow guide opening.

11. A water receiving device as claimed in claim 5,

and along the direction from the drainage part to the diversion port, the distance from the notch of the diversion trench to the bottom of the diversion trench is gradually increased.

12. A water receiving device as claimed in any one of claims 1 to 3, further comprising:

the water receiving tray is arranged on the support.

13. A water receiving device as claimed in claim 12,

a gap is formed between the flow guide structure and the outer surface of the bracket.

14. A water receiving device as claimed in claim 12, wherein the bracket comprises:

the frame body is arranged around the periphery of the water receiving tray and connected with the water receiving tray;

and the reinforcing structure is connected with the frame body.

15. A water receiving device as claimed in claim 14, wherein the reinforcing structure comprises:

a first reinforcing rib;

the second reinforcing ribs are arranged at intervals with the first reinforcing ribs, and any one of the first reinforcing ribs and the second reinforcing ribs is connected with two sides of the frame body;

and the third reinforcing rib is positioned between the first reinforcing rib and the second reinforcing rib, one end of the third reinforcing rib is connected with the first reinforcing rib, and the other end of the third reinforcing rib is connected with the second reinforcing rib.

16. A water receiving device according to any one of claims 1-3,

the water receiving tray is provided with a plurality of corners, the number of the flow guide structures is multiple, and one flow guide structure is arranged at each corner;

wherein, the water conservancy diversion structure is L shape.

17. A heat exchange apparatus, comprising:

water receiving device according to any one of claims 1 to 16.

18. The heat exchange apparatus of claim 17 further comprising:

the heat exchanger is connected with the water receiving device, and the water receiving part of the water receiving tray is communicated with the heat exchanger.

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