CN203824169U - Heat exchanger and heat pump system - Google Patents

Abstract

The utility model discloses a heat exchanger and heat pump system using same. The heat exchanger comprises a first flow collecting pipe and a second flow collecting pipe; preset distance is formed between the first flow collecting pipe and the second flow collecting pipe; a plurality of flat pipes which are arranged between the first flow collecting pipe and the second flow collecting pipe in an interval mode communicate the first flow collecting pipe and the second flow collecting pipe; the first flow collecting pipe and the second flow collecting pipe comprise at least two chambers; the at least two chambers in the first flow collecting pipe or the second flow collecting pipe are communicated through the flat pipes or the at least two chambers in the first flow collecting pipe and the at least two chambers in the second flow collecting pipe are communicated through the flat pipes to form into respective independent flow channels.

Description

Heat exchanger and heat pump

Technical field

The utility model relates to HVAC, automobile, refrigeration and transport field, relates in particular to the heat exchanger for evaporimeter, condenser, water tank, heat pump etc.

Background technology

As shown in Figure 1, for general family expenses or commercial air conditioning system, heat exchanger wherein has inlet/outlet pipe 1,2, and header 3,4 is responsible for distributing and collecting refrigerant, and there is microchannel flat tube 5 inside.In the time of circulation refrigerant, be responsible for the heat transfer between refrigerant and air.Between flat tube 5, be provided with corrugated fin 6 and be responsible for strengthening heat transfer effect.Concrete fluid flow path is as shown in the arrow in figure.When flowing through fin 6 and flat tube 5 under the driving of air at blower fan, owing to having temperature difference between air and refrigerant, by the heat transmission there will be between two media.For condenser application, after Air Flow, heat absorption is flowed out, and for evaporator application, after Air Flow, heat radiation is flowed out.

For conventional heat exchanger, can be partitioned into different streams by installing dividing plate additional; But due to header punching press after flat tube groove, can there is material flange, and if dividing plate can not insert the afflux tube wall of straightway after inserting.There will be the coolant leakage between loop, part refrigerant just enters next loop without heat exchange, causes heat exchanger partial failure.

For evaporimeter and heat pump application, owing to relating to condensed water and frosting defrost problem, the flat tube that it is level that the modes of emplacement of heat exchanger can be put as header is vertical.In order to make the cold medium flux equilibrium of each flat tube inside, can add a pipeline in header inside, on pipeline, make different slotted eyes according to actual conditions and obtain good heat transfer effect.

In order to obtain good heat exchange area, can use two row's heat exchangers.For example, such as, when the application such as in the time that some small spaces are applied, regenerator is applied, and heat exchanger used for automobile air conditioning and water tank are parallel, also can use 2 row's heat exchangers or arrange heat exchanger more.Conventional application as shown in Figure 2.

For above these conventional heat exchangers, along with the flow and heat transfer of refrigerant on flow direction, the temperature of medium side can change, and the temperature of inlet air is consistent, can cause like this heat exchange efficiency unbalanced, and for indoor set heat exchanger used, leaving air temp also can be inhomogeneous, user's comfort reduces.

In view of this, truly have a kind of novel heat exchanger that can address the above problem at least in part need to be provided.

Utility model content

The purpose of this utility model is intended to solve at least one aspect of the above-mentioned problems in the prior art and defect.

In one aspect, the utility model provides a kind of heat exchanger, comprises the first header; The second header, described the first header and the spaced apart preset distance of the second header; Multiple flat tubes are spaced apart and arranged between described the first header and the second header and are communicated with the first header and the second header, wherein, each in described the first header and the second header comprises at least two cavitys, at least two cavitys in described the first header or the second header be interconnected by flat tube or described the first header at least two cavitys be connected to form independently stream separately with at least two cavitys in described the second header by flat tube.

Particularly, each described at least two cavitys of described the first header and the second header comprise the first cavity and the second cavity, the first cavity of described the first header and the first cavity of the second header are separately positioned on the outermost end of heat exchanger, and the second cavity of the second cavity of described the first header and the second header is close to the first cavity setting separately.

Particularly, described first cavity of described the first header and described second cavity of described the second header, described first cavity of described the second header is communicated with to form separately independently stream by described flat tube respectively with described second cavity of described the first header.

Particularly, the first cavity of described the first header and the first cavity of the second header are used separately as the entrance cavity of fluid, and the second cavity of the first header and the second cavity of the second header are used separately as the outlet cavity of fluid.

Particularly, one end of the first flat tube assembly in described flat tube is inserted in the first cavity of the first header, and the other end is inserted in the second cavity of the second header; And one end of the second flat tube assembly in described flat tube is inserted in the first cavity of the second header, and the other end is inserted in the second cavity of the first header.

Particularly, described the first flat tube assembly and the second flat tube assembly are spaced apart and arranged between the first header and the second header, and the first adjacent flat tube assembly or the interval of the second flat tube assembly are identical or different, and the quantity of the first flat tube assembly and the included flat tube of the second flat tube assembly is identical or different.

Particularly, described the first flat tube assembly and the second flat tube assembly is equal in length.

Particularly, described at least one, flat tube at least comprises the first flow and the second runner that extend along described flat tube length direction that are arranged side by side.

Particularly, the described first flow in described flat tube and described the second runner have different length at its two ends place.

Particularly, the described first flow in described flat tube is inserted in the first cavity of the first header at one end, and in the second cavity that first flow is inserted into the second header is stated in other end place; And described the second runner in described flat tube is inserted in the second cavity of the first header at one end, and in the first cavity that the second runner is inserted into the second header is stated in other end place.

Particularly, first flow and the second runner comprise respectively multiple refrigerant passages that extend along described flat tube length direction.

Particularly, described first flow is identical or different with the refrigerant passage number in the second runner.

Particularly, described first flow is identical with the multiple refrigerant passage length in the second runner.

Particularly, first flow and the second runner are arranged side by side along flat tube short transverse.

Particularly, first flow and the second runner are arranged side by side along flat tube width.

Particularly, the end of described flat tube is provided with inclined-plane by cutting sth. askew, and first flow in described flat tube and the second runner are positioned at the different cavity of same header.

Particularly, the top on described inclined-plane is resisted against on the inwall of the first cavity of the first header or the second header.

Particularly, the end of described flat tube has the first side and second side relative with the first side, described the first side is provided with by cutting sth. askew to described second and rolls oblique inclined-plane, on the top on the inclined-plane at the outer rim place of the first side, against the inwall of the second cavity of the first header or the second header or dividing plate wherein, or the top of the flat tube of the second side is against the inwall of the first cavity of the first header or the second header.

Particularly, by multiple the first dividing plates of extending along the first header and the second header length direction by each in the first header and the second header be divided into have described at least two cavitys, described the first dividing plate is provided with the groove that the described flat tube of multiple confessions passes, each in described the first header and the second header be integral type or be assembled by multiple parts.

Particularly, by second partition, the first cavity of the first header and/or the second header is separated into multiple sub-cavitys, and at least one sub-cavity is communicated with inlet tube.

Particularly, in the first cavity of described the first header and/or the second header, be provided with refrigerant distribution member.

Particularly, the first cavity of described the first header and/or the second header is connected with at least two inlet tubes.

Particularly, in described heat exchanger, be provided with three, four or the more independent stream for identical or different fluid.

According on the other hand of the present utility model, a kind of heat pump is provided, described heat pump comprises:

At least one reversal valve, it is configured in the time of heat pump operation heating mode, refrigerant be flowed in closed pipeline with first direction, and in the time of heat pump running refrigerating pattern, makes refrigerant flow with the second direction contrary with first direction in closed pipeline;

Compressor;

At least one indoor heat exchanger;

At least one outdoor heat exchanger,

At least one throttling arrangement, it is arranged in the closed pipeline between described indoor heat exchanger and outdoor heat exchanger, and is configured to reduce the pressure of described refrigerant;

At least one in wherein said indoor and/or outdoor heat exchanger is according to the heat exchanger described in any one in claim 1-23.

Brief description of the drawings

These and/or other aspect of the present utility model and advantage are understood below in conjunction with becoming in accompanying drawing description of preferred embodiments obviously and easily, wherein:

Fig. 1 shows the structural representation of a kind of heat exchanger of the prior art;

Fig. 2 shows the structural representation of two row's heat exchangers of the prior art;

Fig. 3 a shows according to the schematic diagram of the heat exchanger of the first embodiment of the present utility model;

Fig. 3 b shows a variant embodiment of Fig. 3 a;

Fig. 4 a-4d shows the schematic diagram of the structural configuration of the header shown in Fig. 3 a-3b and flat tube;

Fig. 5 shows according to the schematic diagram of the heat exchanger of another embodiment of the present utility model;

Fig. 6 shows according to the schematic diagram of the heat exchanger with distributing pipe of another embodiment of the present utility model;

Fig. 7 shows according to the schematic diagram of the heat exchanger with multiple inlet tubes of another embodiment of the present utility model;

Fig. 8 a-8b shows by different flat tube insertion depths and realizes the independently schematic diagram of stream;

Fig. 9 a-9h shows the schematic diagram of different flat tube cutting schemes;

Figure 10 shows under the cutting scheme of the flat tube shown in Fig. 9 a and 9b flat tube after cutting and the assembling schematic diagram of header;

Figure 11 shows according to the schematic diagram of the heat exchanger of other embodiment of the present utility model;

Figure 12 a-c shows the zoomed-in view of the part that end view, perspective view and the circle of the flat tube in Figure 11 indicate.

Detailed description of the invention

Below by embodiment, and 3a-12c by reference to the accompanying drawings, the technical solution of the utility model is described in further detail.In description, same or analogous drawing reference numeral is indicated same or analogous parts.Followingly with reference to accompanying drawing, the explanation of the utility model embodiment is intended to present general inventive concept of the present utility model to make an explanation, and does not should be understood to a kind of restriction of the present utility model.

Specifically, referring to Fig. 3 a, show according to the heat exchanger 10 described in an embodiment of the present utility model.This heat exchanger 10 comprises the first header 13, the second header 14, multiple flat tube 15 and several fins between adjacent flat tube 15 (not indicating).The first header 13 and the spaced apart preset distance setting of the second header 14, flat tube 15 is spaced apart and arranged between the first header 13 and the second header 14, and communicates with each other.

In one embodiment, the first header 13 or the second header 14 can be configured to comprise respectively at least two cavitys.As shown in Fig. 3 a and 4a-4d, by insert dividing plate 17 in the first header 13 or the second header 14, form two cavitys arranging perpendicular to the bearing of trend of header.The first header 13 comprises first cavity 131 at the outermost end place that is positioned at heat exchanger 10 and the second cavity 132 that next-door neighbour's the first cavity 131 arranges; The second header 14 comprises first cavity 141 at the outermost end place that is positioned at heat exchanger 10 and the second cavity 142 that next-door neighbour's the first cavity 141 arranges.The first cavity 131 of the first header 13 and the first cavity 141 of the second header 14 are used separately as import cavity separately, and the second cavity 132 of the first header 13 and the second cavity 142 of the second header 14 are used separately as outlet cavity separately.Certainly, can also be communicated with the first above-mentioned cavity and the second cavity in other mode, as long as they form independently stream after being communicated with.Certainly, can also as required the first cavity 131 and 141 be used as to outlet cavity, and the second cavity 132 and 142 is as import cavity.

In Fig. 3 b, illustrate, by inserting dividing plate 27 in the direction of the bearing of trend perpendicular to header 13 or 14 further, two cavitys that are arranged side by side along the bearing of trend of header 13 or 14 can be set in header.For example the first header 13 is separated into two of left and right cavity 131 ' and 131 by dividing plate 27 ", correspondingly the second header 14 is separated into two of left and right cavity 141 ' and 141 by another dividing plate 27 ".Like this, refrigerant can upwards flow into another cavity 132 in the first header 13 (by forming at the interior insertion dividing plate 17 of the first header 13 through flat tube 151 from cavity 141 ', as described in Fig. 3 a) in but do not flow into cavity 131 ' or 131 "; flow into cavity 141 by flat tube 152 afterwards " in, and finally from outlet flow out.For another stream independently, refrigerant can flow into downwards in another cavity 142 in the second header 14 through flat tube 153 from cavity 131 ' but not flow into cavity 141 ' or 141 " in; flow into cavity 131 by flat tube 154 afterwards " in, and finally flow out from another outlet.From Fig. 3 b, the cavity of the first header 131 ' is as entrance cavity, and its another cavity 131 " correspondingly as its outlet cavity; The cavity 141 ' of the second header is as entrance cavity, and its another cavity 141 " correspondingly as its outlet cavity.Significantly, these are different from the configuration of the independent stream shown in Fig. 3 a, all form two independently streams but something in common is the heat exchanger shown in Fig. 3 a and Fig. 3 b.

In Fig. 4 a and 4c, 4d, show the header 13 or 14 being assembled by multiple parts.Especially referring to Fig. 4 d, the first header 13 is made up of three parts, for example for example dividing plate 17 is put into, in the groove of profile part (semicircle) 135, and afterwards top profile elements (for example semicircle) 136 is arranged in described groove and on dividing plate 17 (referring to the installation diagram of Fig. 4 c).Different from Fig. 4 c-d, be arranged to integral type at Fig. 4 a median septum 17 and profile part 135, and top profile elements 136 is independently parts.Certainly, also the first header 13 can be arranged to the form of the integral type shown in Fig. 4 b.In this example, offer hole slot by the top at the first header 13 or bottom, and one end of flat tube 15 is inserted in the first header 13.Can understand, the second header 14 can be set in the same manner described above, no longer describe in detail at this.

Certainly,, if wish the independent stream more than two is set in heat exchanger 10 of the present utility model, need in the first and second headers 13 and 14, the cavity more than two be set respectively accordingly.For example, in the time that needs arrange three cavitys in the first header 13, can in the header shown in Fig. 4 a-4d, set up a dividing plate, to be separated into two cavitys by one in the first cavity 131 and the second cavity 132.On described dividing plate, be provided with multiple grooves that pass for flat tube.The like, four, five or more cavity can be set in the first header 13.In like manner, said method is also applicable to the second header 14.

Below will be so that the utility model design of the present utility model as example illustrates of two cavitys to be set respectively in the first header 13 and the second header 14, still the utility model is not limited to this situation from the foregoing.Those skilled in the art can arrange the quantity of the first header 13 and the second header 14 inner chamber body as required.

Referring to Fig. 3 a, the right-hand member of the first cavity 131 of the first header 13 is provided with inlet tube 11, and the right-hand member of the first cavity 141 of the second header 14 is also provided with inlet tube 12.Correspondingly, at the left end of the second cavity 132 of the first header 13 and the second cavity 142 of the second header 14, outlet 18 and 19 is set respectively.In order to form independently stream, the upper end of a part of flat tube (becoming the first flat tube assembly 151 at this) in flat tube 15 is inserted in the first cavity 131 of the first header 13, and lower end is inserted in the second cavity 142 of the second header 14.Like this, from the fluid of inlet tube 11, flow through the first cavity 131 of the first header 13, flow into downwards in the second cavity 142 of the second header 14 by the first flat tube assembly 151 (along the arrow in Fig. 3 a), and finally flows out from outlet 18.

Correspondingly, the upper end of another part flat tube (referred to here as the second flat tube assembly 152) in flat tube 15 is inserted in the second cavity 132 of the first header 13, and lower end is inserted in the first cavity 141 of the second header 14.Like this, from the fluid of inlet tube 12, flow through the first cavity 141 of the second header 14, upwards flow in the second cavity 132 of the first header 13 by the second flat tube assembly 152 (along the arrow in Fig. 3 a), and finally flows out from outlet 19.Hence one can see that, has two independently streams in heat exchanger 10 of the present utility model.

In Fig. 3 a, 3b, demonstrate the first flat tube assembly 151 and the second flat tube assembly 152 and be spaced apart and arranged between the first header 13 and the second header 14, and the quantity of the first flat tube assembly 151 and the second flat tube assembly 152 is all 3 flat tubes.But the interval between the interval between the first adjacent flat tube assembly 151 or the second adjacent flat tube assembly 152 can be the distance of three flat tubes, can be also other distances.In addition, the length of the first flat tube assembly 151 and the second flat tube assembly 152 can equate.

Fig. 5 demonstrates another alternative form of the heat exchanger of Fig. 3 a.Identical with shown in Fig. 3 a of its most of structure, difference is only that the quantity of the first flat tube assembly 151 flat tube included with the second flat tube assembly 152 is different.That is to say, can use flat tube 15 distributed architectures heterogeneous according to the difference in flow field in this example.Can be distributed in the flat tube that uses varying number in two independent streams according to heat transfer effect and wind field.

Figure 5 illustrates in the left side of heat exchanger 10 the first flat tube assembly 151 that comprises 5 flat tubes is set, be close to this first flat tube assembly 151 that comprises 5 flat tubes and be provided with the second flat tube assembly 152 that comprises three flat tubes, be close to this second flat tube assembly 152 that comprises three flat tubes and be provided with another the first flat tube assembly 151 that comprises three flat tubes, and be provided with another the second flat tube assembly 152 that comprises a flat tube on the right side of heat exchanger 10.Can understand by above-mentioned, in heat exchanger structure of the present utility model is arranged, the quantity (or interval) between them of the included flat tube of wherein the first flat tube assembly 151 and the second flat tube assembly 152 can be specifically set as required, to realize uniform heat exchange.

Figure 6 illustrates the example of the heat exchanger 10 with distributing pipe.Heat exchanger structure in Fig. 6 is most of identical with the heat exchanger 10 shown in Fig. 3 a, and difference is only to have set up distributing pipe 21,22.In an embodiment of the present utility model, the first cavity 131 and 141 of the first header 13 and the second header 14 is all the time as import cavity, and their the second cavity 132 and 142 is all used as outlet cavity.Like this, each independently stream can be there is independently install the space of the distribution member of distributing pipe 21,22 etc.As shown in the figure, distributing pipe 21 and 22 is arranged on respectively in the first cavity 131 and 141.

Alternately, in order to realize the uniform distribution of refrigerant or fluid, except the distributing pipe arranging as noted earlier, can also on the first above-mentioned cavity 131 and 141, be provided with at least two inlet tubes, to realize the distribution of refrigerant.

Should be appreciated that and can distribution member be set in the entrance cavity of heat exchanger of the present utility model as required, in order to distribute refrigerant.

Figure 7 illustrates according to the example of the heat exchanger of another embodiment of the present utility model.The structure of the heat exchanger 10 shown in Fig. 7 is substantially identical with the heat exchanger shown in Fig. 3 a with operation principle.But in this example, by the first header 13 (specifically the first cavity 131) and the second header 14 (specifically the first cavity 141) being separated into several sections or several sub-cavitys 24,25 perpendicular to header bearing of trend inserts dividing plate 23.Every sub-cavity 24,25 is respectively arranged with inlet tube 11 or 12.The first all flat tube assemblies and the second flat tube assembly in flat tube 15 all comprise respectively two flat tubes (fluid flow direction is as shown in the arrow by figure).In this example, by using the mode of many inlet tubes, can ensure that the sub-cavity 24 or 25 of every section has balanced refrigerant flow as far as possible.Certainly, in addition, can also in the first cavity of header 13 or 14, not establish sub-cavity, directly on afflux tube wall, connect side by side multiple inlet tubes 11 or 12, in order to distribute refrigerant.Alternately, can also place first dividing plate in the middle of cavity, and all place at the right and left of dividing plate the distributing pipe that the inlet tube common with or inlet tube are separately connected.

In Fig. 8 a and 8b, demonstrate by different flat tubes 15 insertion depths and realized two independently streams (dotted line represents only to show a part for flat tube in this accompanying drawing and in the utility model).In the heat exchanger shown in Fig. 3 a-7 of the present utility model, flat tube 15 can comprise multiple runners that one deck is arranged side by side.As shown in Figure 8 a, the multiple runners in flat tube 15 are all inserted in the first cavity 131 in the first header 13 at one end, and in other end place is all inserted into the second cavity 142 in the second header 14.As shown in Figure 8 b, the multiple runners in flat tube 15 are all inserted in the second cavity 132 of the first header 13 at one end, and in other end place is all inserted into the first cavity 141 in the second header 14.

Referring to Fig. 9 a-9b, in addition, flat tube 15 can also be arranged at least comprise the first flow 155 and the second runner 156 that extend along flat tube length direction.In addition, first flow 155 and the second runner 156 are arranged side by side along the width of flat tube 15.In Fig. 9 a-9h, the cutting scheme that shows the flat tube 15 different by 4 kinds is realized first flow 155 and the second runner 156 is set.As shown in Fig. 9 a and 9b, the first flow 155 in described flat tube and the second runner 156 have different length at its two ends place particularly.Described first flow 155 in described flat tube 15 is inserted in the first cavity 131 of the first header 13 at one end, and in the second cavity 142 that first flow 155 is inserted into the second header 14 is stated in other end place; And described the second runner 156 in described flat tube 15 is inserted in the second cavity 132 of the first header 13 at one end, and in the first cavity 141 that the second runner 156 is inserted into the second header 14 is stated in other end place.

In addition, referring to Fig. 9 c-9d, its set-up mode identical with shown in Fig. 9 a-9b substantially, difference is that first flow 155 is different with the width of the second runner 156.Can understand, those skilled in the art can arrange the width of first flow 155 and the second runner 156 as required.

The object of above-mentioned cutting is, multiple runners at one end place of same flat tube 15 or microchannel are distributed in the different cavity of header 13 or 14.For example, by go out shape as shown in Fig. 9 a-9h (cut away at one end one square, rectangle, oblique angle or roughly trapezium structure) in the end cut of flat tube 15, thereby the runner of having realized flat tube 15 inside after cutting apart is distributed in different cavitys.Supposed to illustrate the insertion state of the flat tube 15 in the first header 13 in Fig. 9 a, 9c, 9e and 9g, the insertion state of this flat tube 15 in the second header 14 has correspondingly been shown in Fig. 9 b, 9d, 9f, 9h, and the runner in known same flat tube 15 is optionally distributed in the different cavity of header.Can understand, cutting scheme described in the utility model is not limited to above-mentioned form, as long as can realize in the different cavity that same runner in flat tube be distributed in header, can adopt any suitable cutting form.

It should be noted that first flow 155 and the second runner 156 comprise respectively the refrigerant passage (not shown at this) that multiple length directions along flat tube 15 extend.Certainly, the number of the refrigerant passage in first flow 155 and the second runner 156 can be identical or different.As shown in Fig. 9 a-d,

First flow 155 is identical with the length of the multiple refrigerant passages in the second runner 156.As shown in Fig. 9 e-9f, the length of the multiple refrigerant passages in first flow 155 and the second runner 156 is not identical,

Especially in Fig. 9 e, shorten gradually from left to right, and just in time contrary in Fig. 9 f, elongated gradually from left to right.In like manner, in Fig. 9 g and 9h, the length of the multiple refrigerant passages in first flow 155 is to be inserted into one end place in the first cavity 131 substantially the same, and to be inserted into other end place in the second cavity 142 elongated gradually from left to right; The length of the multiple refrigerant passages in the second runner 156 is to be inserted into one end place in the first cavity 141 substantially the same, and shortens gradually from left to right at the other end place being inserted in the second cavity 132.

In Fig. 9 e and 9f, the end of flat tube 15 is provided with inclined-plane 157 by cutting sth. askew, and first flow 155 in flat tube 15 and the second runner 156 are positioned at the different cavity of header 13 or 14.The top 158 on inclined-plane 157 is resisted against on the inwall of the first cavity 131 or 141 of header 13 or 14, to locate the insertion depth of flat tube 15 in the time that flat tube 15 is installed.

In Fig. 9 g and 9h, the end being inserted in the first header 13 of described flat tube 15 has the first side 161 and second side 162 relative with the first side 161, described the first side 161 is provided with the inclined-plane 163 tilting to described the second side 162 by cutting sth. askew, on the top on the inclined-plane 163 at the outer rim place of the first side 161, against the inwall of the second cavity 132 of the first header 13 or dividing plate 17 wherein, or the top of the flat tube of the second side 162 is against the inwall of the first cavity 131 of the first header.The structure identical with Fig. 9 g has been shown in Fig. 9 h, and difference is the other end of flat tube 15 to be inserted in the second header 14.Known, the top of the first side 161 and the second side 162 all has the function of the insertion depth of location flat tube 15.In addition, refrigerant passage herein can be stopped up by flowing into part scolder in the junction 164 of first flow 155 and the second runner 156 in the time of welding.Block this refrigerant passage, reduced the heat transfer between the runner both sides refrigerant passage part at this place.

Figure 10 shows the connection diagram of the flat tube 15 shown in Fig. 9 a and 9b.Visible, in this example, same flat tube 15 be by being cut a part in end, realized the first flat tube assembly 151 in above-mentioned heat exchanger 10 and the effect of the second flat tube assembly 152 simultaneously.

Figure 11 shows another example of heat exchanger 10 of the present utility model.In this example, flat tube 15 is configured to the situation as shown in Figure 12 a-c.Namely, be provided with first flow 173 and the second runner 174 in flat tube 15, its short transverse along flat tube 15 is arranged side by side.Particularly, in this example, flat tube 15 is each has the two-layer flow passage structure being arranged side by side, and each layer of flow passage structure has the multiple refrigerant passages that are arranged side by side.In the time of cutting flat tube 15, flat tube 15 is cut along the number of plies of flat tube inner flow passage.In the time that flat tube 15 inserts in header 13 or 14, the refrigerant passage 174 in lower floor's flow passage structure enters in the first cavity 131 of the first header 13, and refrigerant passage 173 in the flow passage structure of upper strata enters in the second cavity 132 of the first header 13.Correspondingly, at the other end place of flat tube 15, the refrigerant passage 174 in lower floor's flow passage structure enters in the second cavity 142 of the second header 14, and refrigerant passage 173 in the flow passage structure of upper strata enters in the first cavity 141 of the second header 14.Concrete flow path, as shown in the arrow of Figure 11, has been realized two kinds of independently streams in this heat exchanger 10.Certainly, flat tube 15 can be arranged to have the form of three laminar flow roads or more multi-layered runner, and in this heat exchanger 10, realize three kinds or more kinds of independently stream.

The end view of one end of the flat tube 15 with two-layer runner has been shown in Figure 12 a.The perspective view of one end of the flat tube 15 of Figure 12 a has been shown in Figure 12 b.The zoomed-in view of the end of the flat tube 15 in the circle in Figure 11 has been shown in Figure 12 c.

In addition, it will be appreciated by those skilled in the art that, can suitably combine as required the various features described in the various embodiments described above of the present utility model, to construct as required needed heat exchanger.

In addition, known above-mentioned heat exchanger can also be used for heat pump.Heat pump comprises: at least one reversal valve, it is configured in the time of heat pump operation heating mode, refrigerant be flowed in closed pipeline with first direction, and in the time of heat pump running refrigerating pattern, makes refrigerant flow with the second direction contrary with first direction in closed pipeline; Compressor, for compression refrigerant; At least one indoor heat exchanger; At least one outdoor heat exchanger, at least one throttling arrangement, it is arranged in the closed pipeline between described indoor heat exchanger and outdoor heat exchanger, and is configured to reduce the pressure of described refrigerant.Particularly, at least one in described indoor and/or outdoor heat exchanger is according to above-mentioned heat exchanger.

Certainly, described outdoor heat exchanger comprises at least two independently streams, and described outdoor heat exchanger has three kinds of alternative mode of operations,

The first mode of operation be in described outdoor heat exchanger at least two independently stream all as evaporimeter operation,

The second mode of operation be in described outdoor heat exchanger at least two independently at least one in stream independently stream is at least in part for carrying out defrosting, and remaining independent stream moves as evaporimeter;

The third mode of operation be in described outdoor heat exchanger at least two independently stream all move as condenser.

Preferably, in the second mode of operation, described at least two independently have a stream to carry out defrosting in stream all the time, and remaining stream moves as evaporimeter.

Heat exchanger described in an embodiment or multiple embodiment that the utility model is above-mentioned has part or all in following advantage or advantage:

1) heat exchanger has at least two independent streams, can be according to different demand manufacture list kind refrigerants or the integrated heat exchanger of multiple refrigerant.

2) header inside is at least divided into two cavitys, coordinates the flat tube of particular design to reach purpose of design of the present utility model.

3) only carry out refrigerant distribution and cut apart stream in the outermost of heat exchanger; Bring in from each, the insertion depth of inducer part flat tube exceedes outlet section part cavity and enters inducer inside cavity, the parts such as distributing pipe easy to use; Due to centre, to cut apart the baffle surface of header more smooth in addition, and the convenient dividing plate that inserts is cut apart stream.

4) balanced heat transfer temperature difference, preferably heat transfer effect.

5) uniform leaving air temp, comfort is better.

6) under special circumstances, single heat exchanger can do two row's heat exchanger use, makes cost lower.

7) avoid using two row's heat exchangers, reduce costs.

8) dividing plate of easily implementing; Because dividing plate is more smooth, dividing plate easily inserts, and leaks probability in reducing.

9), in the time using as heat pump, hoarfrost point equiblibrium mass distribution, extends heat pamp, shortens the defrost time.Conventional heat pump, in the time of frosting, is easily concentrated one end of flat tube.In the utility model, refrigerant can be divided into two different flow directions, frosting situation is more balanced with respect to conventional heat exchanger, can extend heat pamp.In addition, defrost starts defrost from both direction simultaneously, has shortened the defrost time.

These are only embodiment more of the present utility model, those skilled in the art will appreciate that, in the case of not deviating from the principle and spirit of this overall utility model design, can make a change these embodiment, scope of the present utility model limits with claim and their equivalent.

Claims (26)

1. a heat exchanger, comprises the first header; The second header, described the first header and the spaced apart preset distance of the second header; Multiple flat tubes are spaced apart and arranged between described the first header and the second header and are communicated with the first header and the second header, it is characterized in that,

Each in described the first header and the second header comprises at least two cavitys, at least two cavitys in described the first header or the second header be interconnected by flat tube or described the first header at least two cavitys be connected to form independently stream separately with at least two cavitys in described the second header by flat tube.

2. heat exchanger according to claim 1, is characterized in that,

Each described at least two cavitys of described the first header and the second header comprise the first cavity and the second cavity, the first cavity of described the first header and the first cavity of the second header are separately positioned on the outermost end of heat exchanger, and the second cavity of the second cavity of described the first header and the second header is close to the first cavity setting separately.

3. heat exchanger according to claim 2, is characterized in that,

Described first cavity of described the first header and described second cavity of described the second header, described first cavity of described the second header is communicated with to form separately independently stream by described flat tube respectively with described second cavity of described the first header.

4. heat exchanger according to claim 3, is characterized in that,

The first cavity of described the first header and the first cavity of the second header are used separately as the entrance cavity of fluid, and the second cavity of the first header and the second cavity of the second header are used separately as the outlet cavity of fluid.

5. heat exchanger according to claim 2, is characterized in that,

One end of the first flat tube assembly in described flat tube is inserted in the first cavity of the first header, and the other end is inserted in the second cavity of the second header; And one end of the second flat tube assembly in described flat tube is inserted in the first cavity of the second header, and the other end is inserted in the second cavity of the first header.

6. heat exchanger according to claim 5, is characterized in that,

Described the first flat tube assembly and the second flat tube assembly are spaced apart and arranged between the first header and the second header, and the first adjacent flat tube assembly or the interval of the second flat tube assembly are identical or different, and the quantity of the first flat tube assembly and the included flat tube of the second flat tube assembly is identical or different.

7. heat exchanger according to claim 5, is characterized in that,

Described the first flat tube assembly and the second flat tube assembly equal in length.

8. heat exchanger according to claim 2, is characterized in that,

Described at least one, flat tube at least comprises the first flow and the second runner that extend along described flat tube length direction that are arranged side by side.

9. heat exchanger according to claim 8, is characterized in that,

Described first flow in described flat tube and described the second runner have different length at its two ends place.

10. heat exchanger according to claim 9, is characterized in that,

Described first flow in described flat tube is inserted in the first cavity of the first header at one end, and in the second cavity that first flow is inserted into the second header is stated in other end place; And described the second runner in described flat tube is inserted in the second cavity of the first header at one end, and in the first cavity that the second runner is inserted into the second header is stated in other end place.

11. heat exchangers according to claim 8, is characterized in that,

First flow and the second runner comprise respectively multiple refrigerant passages that extend along described flat tube length direction.

12. heat exchangers according to claim 11, is characterized in that,

Described first flow is identical or different with the refrigerant passage number in the second runner.

13. heat exchangers according to claim 12, is characterized in that,

Described first flow is identical with the multiple refrigerant passage length in the second runner.

14. heat exchangers according to claim 8, is characterized in that,

First flow and the second runner are arranged side by side along flat tube short transverse.

15. heat exchangers according to claim 8, is characterized in that,

First flow and the second runner are arranged side by side along flat tube width.

16. heat exchangers according to claim 8, is characterized in that,

The end of described flat tube is provided with inclined-plane by cutting sth. askew, and first flow in described flat tube and the second runner are positioned at the different cavity of same header.

17. heat exchangers according to claim 16, is characterized in that,

The top on described inclined-plane is resisted against on the inwall of the first cavity of the first header or the second header.

18. heat exchangers according to claim 8, is characterized in that,

The end of described flat tube has the first side and second side relative with the first side, described the first side is provided with by cutting sth. askew to described second and rolls oblique inclined-plane, on the top on the inclined-plane at the outer rim place of the first side, against the inwall of the second cavity of the first header or the second header or dividing plate wherein, or the top of the flat tube of the second side is against the inwall of the first cavity of the first header or the second header.

19. according to the heat exchanger described in any one in claim 1-18, it is characterized in that,

By multiple the first dividing plates of extending along the first header and the second header length direction by each in the first header and the second header be divided into have described at least two cavitys, described the first dividing plate is provided with the groove that the described flat tube of multiple confessions passes, each in described the first header and the second header be integral type or be assembled by multiple parts.

20. according to the heat exchanger described in any one in claim 2-18, it is characterized in that,

By second partition, the first cavity of the first header and/or the second header is separated into multiple sub-cavitys, and at least one sub-cavity is communicated with inlet tube.

21. according to the heat exchanger described in any one in claim 2-18, it is characterized in that,

In the first cavity of described the first header and/or the second header, be provided with refrigerant distribution member.

22. according to the heat exchanger described in any one in claim 2-18, it is characterized in that,

The first cavity of described the first header and/or the second header is connected with at least two inlet tubes.

23. heat exchangers according to claim 1, is characterized in that,

In described heat exchanger, be provided with three, four or the more independent stream for identical or different fluid.

24. 1 kinds of heat pumps, described heat pump comprises:

At least one reversal valve, it is configured in the time of heat pump operation heating mode, refrigerant be flowed in closed pipeline with first direction, and in the time of heat pump running refrigerating pattern, makes refrigerant flow with the second direction contrary with first direction in closed pipeline;

Compressor;

At least one indoor heat exchanger;

At least one outdoor heat exchanger,

At least one throttling arrangement, it is arranged in the closed pipeline between described indoor heat exchanger and outdoor heat exchanger, and is configured to reduce the pressure of described refrigerant;

It is characterized in that,

At least one in described indoor and/or outdoor heat exchanger is according to the heat exchanger described in any one in claim 1-23.

25. heat pumps according to claim 24, is characterized in that,

Described outdoor heat exchanger comprises at least two independently streams,

Described outdoor heat exchanger has three kinds of alternative mode of operations,

The first mode of operation be in described outdoor heat exchanger at least two independently stream all as evaporimeter operation,

The second mode of operation be in described outdoor heat exchanger at least two independently at least one in stream independently stream is at least in part for carrying out defrosting, and remaining independent stream moves as evaporimeter;

The third mode of operation be in described outdoor heat exchanger at least two independently stream all move as condenser.

26. heat pumps according to claim 25, is characterized in that,

In the second mode of operation, described at least two independently have a stream to carry out defrosting in stream all the time, and remaining stream moves as evaporimeter.