CN105716449A - Heat exchanger structure - Google Patents

Abstract

The invention provides a heat exchanger structure, and belongs to the field of heat exchange equipment. The heat exchanger structure comprises a heat exchanger body, a first header pipe and a second header pipe; the first header pipe is provided with a medium flowing-in part, a medium flowing-out part and a separating plate, an inlet is formed in the medium flowing-in part, and an outlet is formed in the medium flowing-out part; the heat exchanger body is provided with a plurality of first pipes and a plurality of second pipes, one end of each first pipe is communicated with the medium flowing-in part, the other end of each first pipe is communicated with the second header pipe, one end of each second pipe is communicated with the second header pipe, and the other end of each second pipe is communicated with the medium flowing-out part; and the medium flowing-in part and the medium flowing-out part are separated through the separating plate, and an opening is formed in one side, far away from the first header pipe, of the separating plate. By means of the heat exchanger structure, heat stress, generated by overlarge temperature differences, of the medium flowing-in part and the medium flowing-out part can be eliminated, so that the phenomenon that the first pipes and the second pipes lose efficiency due to heat stress is avoided, and leakage and efficacy losing of the heat exchanger are prevented.

Description

A kind of heat converter structure

Technical field

The present invention relates to heat-exchange apparatus field, in particular to a kind of heat converter structure.

Background technology

Heat exchanger (heatexchanger), is the equipment that the partial heat of hot fluid passes to cold flow body, also known as heat exchanger.Heat exchanger is used to make heat be delivered to cold flow body from hot fluid, with the device of the technological requirement of satisfied regulation, is a kind of commercial Application of convection heat transfer' heat-transfer by convection and conduction of heat.Existing heat exchanger it is possible that flat tube failure phenomenon, causes heat exchanger leakage failure in use.

Summary of the invention

The invention provides a kind of heat converter structure, it is intended to improve the problems referred to above.

The present invention is achieved in that

A kind of heat converter structure, including heat exchanger body, first header and the second header, described first header is provided with medium inflow part, medium outflow portion and dividing plate, described medium inflow part is provided with import, described medium outflow portion is provided with outlet, described heat exchanger body is provided with multiple first pipeline and multiple second pipe, one end of described first pipeline connects with described medium inflow part, the other end connects with described second header, one end of described second pipe connects with described second header, the other end connects with described medium outflow portion, described medium inflow part and described medium outflow portion are separated by described dividing plate, described dividing plate arranges opening away from the side of described first header.

Further, in presently preferred embodiments of the present invention, described first header is provided with septalium, described septalium is arranged between described medium inflow part and described medium outflow portion, described dividing plate embeds described septalium, and described dividing plate is fixing with the part of the described first corresponding described septalium of header to be connected.

Further, in presently preferred embodiments of the present invention, the width of the notch of described septalium is more than the width of the bottom land of described septalium.

Further, in presently preferred embodiments of the present invention, described septalium is V-shaped groove.

Further, in presently preferred embodiments of the present invention, described dividing plate includes that partition portion, the first connecting portion and the second connecting portion, described first connecting portion and described second connecting portion are fixing with described partition portion respectively to be connected, and described opening is formed by described first connecting portion and described second connecting portion connection.

Further, in presently preferred embodiments of the present invention, the described partition portion described septalium of traverse stretches in described first header and is connected with the inwall of described first header, the part of the outside of described first connecting portion described septalium corresponding to described medium inflow part connects, the part of the outside of described second connecting portion described septalium corresponding to described medium outflow portion connects, and the inner side of the inner side of described first connecting portion and described second connecting portion forms described opening.

Further, in presently preferred embodiments of the present invention, one end of described first connecting portion is connected with described partition portion, one end of described second connecting portion is connected with described partition portion, and described first connecting portion is obliquely installed privately and forms described opening mutually with described second connecting portion away from the one end in described partition portion away from the one end in described partition portion.

Further, in presently preferred embodiments of the present invention, described first connecting portion is connected formation V-arrangement with described second connecting portion, and described opening is V-arrangement.

Further, in presently preferred embodiments of the present invention, described first connecting portion and described second connecting portion are arc, and described opening is arc.

Further, in presently preferred embodiments of the present invention, described opening is through along the bearing of trend of described septalium.

Heat converter structure provided by the invention provides the benefit that: this heat converter structure is operationally, treat that the medium of heat exchange is entered the medium inflow part of the first header by import, branch in multiple first pipeline from medium inflow part again, flow in the second header through the first pipeline and collect, branched in multiple second pipe by the second header again, then it flow to medium outflow portion through second pipe, finally flow out from outlet.Being provided with working media in heat exchanger body, working media can be air, water etc., and in the media flow process treating heat exchange, working media can carry out heat exchange with medium in pipe.This heat converter structure is owing to being provided with opening on dividing plate, gap is there is in medium inflow part and medium outflow portion in the side being provided with opening, medium inflow part and medium outflow portion thermal stress produced by excessive temperature differentials can be eliminated, thus avoiding the first pipeline and second pipe to cause the phenomenon of inefficacy because of thermal stress, it is therefore prevented that heat exchanger leakage failure.

Accompanying drawing explanation

In order to be illustrated more clearly that the technical scheme of the embodiment of the present invention, the accompanying drawing used required in embodiment will be briefly described below, it is to be understood that, the following drawings illustrate only certain embodiments of the present invention, therefore the restriction to scope it is not construed as, for those of ordinary skill in the art, under the premise not paying creative work, it is also possible to obtain other relevant accompanying drawings according to these accompanying drawings.

The overall structure schematic diagram of the heat converter structure that Fig. 1 provides for the embodiment of the present invention；

The partial structurtes schematic diagram at the first header place of the heat converter structure that Fig. 2 provides for the embodiment of the present invention；

First header of the heat converter structure that Fig. 3 provides for the embodiment of the present invention structural representation when unassembled dividing plate；

The structural representation of the dividing plate of the heat converter structure that Fig. 4 provides for the embodiment of the present invention.

Figure acceptance of the bid note is respectively as follows:

Heat converter structure 10；

Heat exchanger body 100；First pipeline 101；Second pipe 102；Fin 103；

First header 200；Medium inflow part 210；Import 211；

Medium outflow portion 220；Outlet 221；

Dividing plate 230；Opening 231；Partition portion 232；First connecting portion 233；Second connecting portion 234；

Septalium 240；

Second header 300.

Detailed description of the invention

Heat exchanger (heatexchanger), is the equipment that the partial heat of hot fluid passes to cold flow body, also known as heat exchanger.Heat exchanger is used to make heat be delivered to cold flow body from hot fluid, with the device of the technological requirement of satisfied regulation, is a kind of commercial Application of convection heat transfer' heat-transfer by convection and conduction of heat.Existing heat exchanger it is possible that flat tube failure phenomenon, causes heat exchanger leakage failure in use.

The designer of the present invention studies discovery, produce flat tube failure phenomenon because be, the medium temperature difference of inflow heat exchanger and outflow heat exchanger is bigger, cause that this side header can produce thermal stress because expanding with heat and contract with cold, and the flat tube wall thickness being connected with this side header to be thinner than header, meeting stress when heat exchanger uses is tired and produces to destroy, and ultimately results in heat exchanger leakage failure.

Given this, the designer of the present invention is by long-term exploration and trial, and experiment repeatedly and effort, constantly reform and innovation, devise a kind of heat converter structure 10, medium inflow part 210 and medium outflow portion 220 thermal stress produced by excessive temperature differentials can be eliminated, thus avoiding the first pipeline 101 and second pipe 102 to cause the phenomenon of inefficacy because of thermal stress, it is therefore prevented that heat exchanger leakage failure.

For making the purpose of the embodiment of the present invention, technical scheme and advantage clearly, below in conjunction with the accompanying drawing in the embodiment of the present invention, technical scheme in the embodiment of the present invention is clearly and completely described, obviously, described embodiment is a part of embodiment of the present invention, rather than whole embodiments.Generally can with various different configurations arrange and design with the assembly of the embodiment of the present invention that illustrate described in accompanying drawing herein.Therefore, below the detailed description of the embodiments of the invention provided in the accompanying drawings is not intended to limit claimed the scope of the present invention, but is merely representative of the selected embodiment of the present invention.Based on the embodiment in the present invention, the every other embodiment that those of ordinary skill in the art obtain under not making creative work premise, broadly fall into the scope of protection of the invention.

In describing the invention, it will be appreciated that, term " width ", " thickness ", " on ", D score, " interior ", orientation or the position relationship of the instruction such as " outward " are based on orientation shown in the drawings or position relationship, or this invention product orientation usually put or position relationship when using, or the orientation usually understood of those skilled in the art or position relationship, it is for only for ease of the description present invention and simplifies description, rather than the equipment of instruction or hint indication or element must have specific orientation, with specific azimuth configuration and operation, therefore it is not considered as limiting the invention.

Additionally, term " first ", " second " are only for descriptive purposes, and it is not intended that indicate or imply relative importance or the implicit quantity indicating indicated technical characteristic.Thus, define " first ", the feature of " second " can express or implicitly include one or more these features.In describing the invention, " multiple " are meant that two or more, unless otherwise expressly limited specifically.

In the present invention, unless otherwise clearly defined and limited, the term such as term " connection ", " fixing " should be interpreted broadly, for instance, it is possible to it is fixing connection, it is also possible to be removably connect, or integral；Can be mechanically connected, it is also possible to be electrical connection；Can be joined directly together, it is also possible to be indirectly connected to by intermediary, it is possible to be connection or the interaction relationship of two elements of two element internals.For the ordinary skill in the art, it is possible to understand above-mentioned term concrete meaning in the present invention as the case may be.

In the present invention, unless otherwise clearly defined and limited, fisrt feature second feature it " on " or D score can include the first and second features and directly contact, it is also possible to include the first and second features and be not directly contact but by the other characterisation contact between them.

Embodiment

The overall structure schematic diagram of the heat converter structure 10 that Fig. 1 provides for the embodiment of the present invention；The partial structurtes schematic diagram at the first header 200 place of the heat converter structure 10 that Fig. 2 provides for the embodiment of the present invention；Referring to Fig. 1 and Fig. 2, present embodiments provide a kind of heat converter structure 10, this heat converter structure 10 includes heat exchanger body the 100, first header 200 and the second header 300.

First header 200 is provided with medium inflow part 210, medium outflow portion 220 and dividing plate 230.Medium inflow part 210 is provided with import 211, medium outflow portion 220 is provided with outlet 221.Heat exchanger body 100 is provided with multiple first pipeline 101 and multiple second pipe 102.One end of first pipeline 101 connects with medium inflow part 210, and the other end and the second header 300 connect, and one end of second pipe 102 connects with the second header 300, and the other end connects with medium outflow portion 220.

Wherein, the first pipeline 101 and second pipe 102 are preferably flat tube, are provided with fin 103, it is possible to further function as the effect of heat exchange between two adjacent pipelines.

Medium inflow part 210 is separated by dividing plate 230 with medium outflow portion 220, the effect of dividing plate 230 is medium inflow part 210 and medium outflow portion 220 to be separated, after the medium entrance import 211 of heat exchange enters medium inflow part 210, directly will not flow to medium outflow portion 220 from medium inflow part 210, but flow in multiple first pipeline 101 and carry out heat exchange.The quantity of dividing plate 230 can be one, it is also possible to is multiple, and is not limited as.

The structural representation of the dividing plate 230 of the heat converter structure 10 that Fig. 4 provides for the embodiment of the present invention；Referring to Fig. 4, dividing plate 230 includes partition portion the 232, first connecting portion 233 and the second connecting portion 234, and the first connecting portion 233 and the second connecting portion 234 are fixing with partition portion 232 respectively to be connected, and the first connecting portion 233 and the second connecting portion 234 connect formation opening 231.

First header 200 of the heat converter structure 10 that Fig. 3 provides for the embodiment of the present invention structural representation when unassembled dividing plate 230；Referring to Fig. 3, the first header 200 is provided with septalium 240.Septalium 240 is arranged between medium inflow part 210 and medium outflow portion 220.Septalium 240 is groove, by through inside the lateral of the first header 200.Septalium 240 is preferably strip, and the thickness direction along heat exchanger body 100 extends.

Referring to Fig. 1～Fig. 4, the partition portion 232 of dividing plate 230 embeds in septalium 240, and cuts off portion 232 and stretch in the first header 200 through septalium 240, then is connected with the inwall of the first header 200.As preferably, what the connected mode of dividing plate 230 and the first header 200 adopted is Welding.After dividing plate 230 and the first header 200 erection welding, medium inflow part 210 and medium outflow portion 220 are separated by partition portion 232.

The part of the outside septalium 240 corresponding to medium inflow part 210 of the first connecting portion 233 connects, the part of the outside septalium 240 corresponding to medium outflow portion 220 of the second connecting portion 234 connects, and the inner side of the inner side of the first connecting portion 233 and the second connecting portion 234 forms opening 231.Opening 231 is through along the bearing of trend of septalium 240.

The designer of the present invention finds, the medium temperature difference of medium inflow part 210 and medium outflow portion 220 is bigger, causing that the first header 200 can produce thermal stress because expanding with heat and contract with cold, thermal stress can cause the first pipeline 101 and second pipe 102 deformation failure, makes heat exchanger produce leakage failure.

In order to solve this problem, by arranging opening 231, medium inflow part 210 and medium outflow portion 220 is made to have gap in the outside of the first header 200, say, that medium inflow part 210 and medium outflow portion 220 are not joined directly together in this side, separate, there is in the middle of both gap.The existence in this gap can eliminate because medium flows into, flows out thermal stress produced by excessive temperature differentials, thus solving the problem because thermal stress causes the first pipeline 101 or second pipe 102 to deform leakage failure.

Refer to Fig. 1～Fig. 4, in the present embodiment, opening 231 is to be connected by the first connecting portion 233 and the second connecting portion 234 to be formed, certainly, opening 231 can also adopt other versions, as long as dividing plate 230 is provided with opening 231 away from the side of the first header 200, it is possible to make medium inflow part 210 and medium outflow portion 220 produce gap.

As preferably, one end of first connecting portion 233 is connected with partition portion 232, one end of second connecting portion 234 is connected with partition portion 232, and the first connecting portion 233 is obliquely installed privately and forms opening 231 mutually with the second connecting portion 234 away from the one end in partition portion 232 away from the one end in partition portion 232.It is to say, the first connecting portion 233 and the second connecting portion 234 open laterally, thus forming opening 231.It addition, the width of the notch of septalium 240 is more than the width of the bottom land of septalium 240, namely in the part of the corresponding septalium 240 of the first header 200, the gap of the part outside being positioned at is more than the gap of the part being positioned at inner side.So, the dividing plate 230 of outer can coordinate more tight with septalium 240, improves the effect eliminating thermal stress.

Preferably, the first connecting portion 233 is connected formation v-shaped structure with the second connecting portion 234, and the opening 231 namely formed is V-arrangement.Therefore, this dividing plate 230 may be considered the dividing plate 230 of V-arrangement.The first connecting portion 233 and the second connecting portion 234 so can be made from inside to outside uniformly to open, the distance in gap from inside to outside uniformly increases, so can strengthen the effect eliminating thermal stress, prevent the problem that the first pipeline 101 and second pipe 102 are deformed leakage failure because of thermal stress further.

Correspondingly, septalium 240 is V-shaped groove.The septalium 240 of V-arrangement can coordinate better with the dividing plate 230 of V-arrangement, connects more tight, is conducive to improving the effect eliminating thermal stress.

Certainly, the shape of opening 231 can also be other shapes, as long as medium inflow part 210 and medium outflow portion 220 exist gap.Such as, the first connecting portion 233 and the second connecting portion 234 are arc, and the opening 231 that both are formed is arc, can reach to eliminate the effect of thermal stress equally.

It addition, dividing plate 230 can adopt interior stifled structure, it would however also be possible to employ the structure of outsourcing.

Structure stifled in dividing plate 230 refers to, when installing dividing plate 230, is that the inside from the first header 200 is installed, and dividing plate 230 is connected with the inwall of the part that the first header 200 is positioned at septalium 240.Preferably, the inwall of both sides up and down of the part that the first connecting portion 233 and the second connecting portion 234 are positioned at septalium 240 respectively with the first header 200 is connected.So, septalium 240 need not make the shape that wide inner side, outside is narrow, and shape is more varied, and installs also very convenient.

The structure of dividing plate 230 outsourcing refers to, when installing dividing plate 230, is that the outside from the first header 200 is installed, and dividing plate 230 is positioned at the part of septalium 240 and is connected and encases the lateral wall of this part with the first header 200.Preferably, first connecting portion 233 and the second connecting portion 234 respectively connect the flat board of an arc, two flat boards connect the wing plate forming an annular, when dividing plate 230 is installed, the part that first connecting portion 233 and the second connecting portion 234 are positioned at septalium 240 with the first header 200 respectively is connected, meanwhile, wing plate and first header 200 of annular connect near the part of septalium 240, and the wing plate of annular forms the structure of a circle outsourcing around septalium 240.So, easy for installation, stable connection, the inside structure of dividing plate 230 can be played a protective role by the wing plate of annular, and, prevent the deformation that thermal stress produces further.

Dividing plate 230 both can adopt the structure of integral type, i.e. the whole as a whole structure of dividing plate 230；Can also adopting split-type structural, namely multi-blocked structure connects formation dividing plate 230, for instance, dividing plate 230 is divided into laterally zygomorphic two pieces, couples together at mid portion and forms an overall dividing plate 230.As long as dividing plate 230 is provided with opening 231.

In sum, refer to Fig. 1～Fig. 4, this heat converter structure 10 is operationally, treat that the medium of heat exchange is entered the medium inflow part 210 of the first header 200 by import 211, branch in multiple first pipeline 101 from medium inflow part 210 again, flow in the second header 300 through the first pipeline 101 and collect, then branched in multiple second pipe 102 by the second header 300, then it flow to medium outflow portion 220 through second pipe 102, finally from outlet 221 outflow.Being provided with working media in heat exchanger body 100, working media can be air, water etc., and in the media flow process treating heat exchange, working media can carry out heat exchange with medium in pipe.

This heat converter structure 10 is owing to being provided with opening 231 on dividing plate 230, gap is there is in medium inflow part 210 and medium outflow portion 220 in the side being provided with opening 231, medium inflow part 210 and medium outflow portion 220 thermal stress produced by excessive temperature differentials can be eliminated, thus avoiding the first pipeline 101 and second pipe 102 to cause the phenomenon of inefficacy because of thermal stress, it is therefore prevented that heat converter structure 10 leakage failure.

The foregoing is only the preferred embodiments of the present invention, be not limited to the present invention, for a person skilled in the art, the present invention can have various modifications and variations.All within the spirit and principles in the present invention, any amendment of making, equivalent replacement, improvement etc., should be included within protection scope of the present invention.

Claims (10)

1. a heat converter structure, it is characterized in that, including heat exchanger body, first header and the second header, described first header is provided with medium inflow part, medium outflow portion and dividing plate, described medium inflow part is provided with import, described medium outflow portion is provided with outlet, described heat exchanger body is provided with multiple first pipeline and multiple second pipe, one end of described first pipeline connects with described medium inflow part, the other end connects with described second header, one end of described second pipe connects with described second header, the other end connects with described medium outflow portion, described medium inflow part and described medium outflow portion are separated by described dividing plate, described dividing plate arranges opening away from the side of described first header.

2. heat converter structure according to claim 1, it is characterized in that, described first header is provided with septalium, described septalium is arranged between described medium inflow part and described medium outflow portion, described dividing plate embeds described septalium, and described dividing plate is fixing with the part of the described first corresponding described septalium of header to be connected.

3. heat converter structure according to claim 2, it is characterised in that the width of the notch of described septalium is more than the width of the bottom land of described septalium.

4. heat converter structure according to claim 3, it is characterised in that described septalium is V-shaped groove.

5. heat converter structure according to claim 2, it is characterized in that, described dividing plate includes partition portion, the first connecting portion and the second connecting portion, described first connecting portion and described second connecting portion are fixing with described partition portion respectively to be connected, and described opening is formed by described first connecting portion and described second connecting portion connection.

6. heat converter structure according to claim 5, it is characterized in that, the described partition portion described septalium of traverse stretches in described first header and is connected with the inwall of described first header, the part of the outside of described first connecting portion described septalium corresponding to described medium inflow part connects, the part of the outside of described second connecting portion described septalium corresponding to described medium outflow portion connects, and the inner side of the inner side of described first connecting portion and described second connecting portion forms described opening.

7. heat converter structure according to claim 6, it is characterized in that, one end of described first connecting portion is connected with described partition portion, one end of described second connecting portion is connected with described partition portion, and described first connecting portion is obliquely installed privately and forms described opening mutually with described second connecting portion away from the one end in described partition portion away from the one end in described partition portion.

8. heat converter structure according to claim 7, it is characterised in that described first connecting portion is connected formation V-arrangement with described second connecting portion, and described opening is V-arrangement.

9. heat converter structure according to claim 7, it is characterised in that described first connecting portion and described second connecting portion are arc, and described opening is arc.

10. the heat converter structure according to any one of claim 2-9, it is characterised in that described opening is through along the bearing of trend of described septalium.