CN205066522U - A triangle -shaped finned plate heat exchanger that is used for bur that sets up of non -azeotropic multi -component mixture condensation - Google Patents

Abstract

The utility model provides a triangle -shaped finned plate heat exchanger that is used for bur that sets up of non -azeotropic multi -component mixture condensation, finned plate heat exchanger is including slab parallel mutually, set up the fin between the slab, the fin is including the inclined part who favours the slab, through stamping mode processing bur on inclined part to the fluid that makes the inclined part both sides passes through the hole intercommunication that inclined part went up stamping mode formation, the bur outwards extends along the mixture flow direction from inclined part. The utility model provides a new finned plate heat exchanger who uses in the non -azeotropic multi -component mixture condensation that is applicable to to the condensation of solving the different mixed medium of multicomponent of boiling point in order to improve heat exchange efficiency, reduces flowing resistance of fluid.

Description

A kind of triangular plate fin heat exchanger that bur is set for the condensation of non-azeotrope multicomponent mixture

Technical field

The utility model belongs to field of heat exchangers, particularly relates to the heat exchanger that a kind of different boiling blending agent condensation uses, belongs to the field of heat exchangers of F28D.

Background technology

The condensation of different boiling blending agent is the main processes of natural gas liquefaction (main component is boiling point-162 DEG C of methane, boiling point-88 DEG C of ethane, boiling point-42 DEG C of propane etc.), air separation, azeotrope refrigeration, oil or the industry such as cracking waste plastics, biogas production.For reducing technical process loss, this type of production technology wishes to cool according to temperature rank the component separating out different boiling step by step, self also carries out exchange heat with one cold-producing medium or product in different temperatures interval, therefore requires that condensing plant conveniently realizes the heat exchange simultaneously of multiply medium.Conveniently can realize equipment mainly spiral winding heat exchange of heat pipe and the plate-fin heat exchanger two kinds of multiply medium heat exchange simultaneously at present.Spiral winding heat exchange of heat pipe is shell structure, and pressure-bearing is higher, and application is comparatively extensive, but is difficult to take enhanced heat transfer measure, and the coefficient of heat transfer is lower, and volume and weight is difficult to reduction.Plate-fin heat exchanger is along with the improvement of manufacturing process in recent years, and bearing capacity improves gradually., there is in a lot of occasions such as natural gas liquefactions the trend replacing winding pipe heat exchanger in the advantage higher, compacter with its heat transfer coefficient, weight is lighter.

Although plate-fin heat exchanger can provide the higher coefficient of heat transfer equally with under the variable working condition of condensation phase in boiling, the fin configuration of existing plate-fin heat exchanger is mainly for the mechanismic design of single-phase medium (emphasis is gas phase media) heat exchange: plain fin extends heat exchange area and reduces hydraulic diameter; Corrugated fin, saw tooth fin, louvered fin are the thinning boundary layers of disturbance fluid on expanding area basis; Be recognized the fin with apertures, the sheet band fin that are applicable to phase-change heat-exchange in the continuity for liquid film can be destroyed during condensing heat-exchange, but to be also proved effect in high reynolds number operating mode and to have superiority unlike plain fin.

The thermal resistance mechanism of non-azeotrope multicomponent blending agent condensation in natural gas liquefaction has obvious difference with pure component material condensation, and theory analysis and experiment have proved that the coefficient of heat transfer obviously reduces than pure component condensation.The existing research to non-azeotrope blending agent condensing heat-exchange is focusing more on the operating mode containing a kind of on-condensible gas, adopt the measures such as low groove, Artificial roughness surface to reduce average thickness of liquid film and be proved remarkably productive measure when pure component condensation, sometimes not obvious containing effect in on-condensible gas situation.And the condensing heat-exchange process of natural gas liquefaction, petroleum cracking industry and mechanism more complicated, condensation process comprises two or more on-condensible gases usually, and heat exchange situation is more complicated.

For the problems referred to above, the utility model provides a kind of new plate-fin heat exchanger, thus solves the condensation of the different multicomponent blending agent of boiling point.

Utility model content

The utility model provides a kind of new plate-fin heat exchanger, thus solves the condensation of the different multicomponent blending agent of boiling point, to improve heat exchange efficiency, reduces fluid flow resistance.

To achieve these goals, the technical solution of the utility model is as follows:

A kind of plate-fin heat exchanger for the condensation of non-azeotrope multicomponent mixture, described plate-fin heat exchanger comprises plate parallel to each other, between described plate, fin is set, described fin comprises the sloping portion favouring plate, it is characterized in that, sloping portion processes bur by impact style, thus the hole that the fluid of sloping portion both sides is formed by impact style on sloping portion is communicated with; Described bur stretches out from sloping portion along mixture flow direction.

As preferably, described fin is triangular form fin, and described fin comprises the sloping portion described in being connected with upper and lower plate, forms triangle between adjacent fin and plate.

As preferably, along the drift angle of triangular fin towards leg-of-mutton base, the bur length L extended in triangle runner is increasing.

As preferably, along the drift angle of triangular fin towards leg-of-mutton base, the amplitude that L increases is increasing.

As preferably, described bur is isosceles triangle, and the base of described isosceles triangle is arranged on sloping portion.

As preferably, sloping portion is arranged arranges bur more, and the bur of described adjacent row is stagger arrangement distribution.

As preferably, sloping portion is arranged multiple bur, described bur extends to the not homonymy of sloping portion.

As preferably, sloping portion is arranged arranges bur more, and adjacent row's bur extends to the not homonymy of sloping portion.

As preferably, sloping portion is arranged arranges bur more, and along the flow direction of mixture, the distance of often arranging between bur is increasing.

As preferably, forming triangle between described adjacent fin and plate is equilateral triangle, described bur is isosceles triangle, the base of described isosceles triangle is arranged on sloping portion, the distance of adjacent plate is H, and the length on isosceles triangle base is h, and the drift angle of isosceles triangle is b, the angle of the bearing of trend of described bur and the flow direction of mixture is a, meets following formula:

The triangle that sloping portion and plate are formed is equilateral triangle, described bur is isosceles triangle, the base of described isosceles triangle is arranged on sloping portion, the length on isosceles triangle base is h, the drift angle of isosceles triangle is b, the angle of the bearing of trend of described bur and the flow direction of mixture is a, meets following formula:

7*h/H=c1*Ln (L*sin (a)/w)+c2, wherein 0.19<c1<0.20,0.64<c2<0.66,

Sin (b/2)=c3-c4*Ln (sin (a)), wherein=0.47<c3<0.48,0.34<c4<0.36;

Wherein=15 ° of <a<66 °, 55 ° of <b<165 °, H=6-14mm;

Wherein Ln is logarithmic function;

0.11<L*sin(a)/w<0.25，0.23<7*h/H<0.40；

H be with the relative face of adjacent plate between distance, W is being parallel to plate direction and is extending to the distance of equilateral triangle adjacent edge with the mid point on isosceles triangle base selecting on equilateral triangle, and L is the distance of summit to base mid point of isosceles triangle.

As preferably, containing on-condensible gas in non-azeotrope multicomponent mixture.

As preferably, the angle of the bearing of trend of described bur and the flow direction of mixture is a, and same sloping portion arranges multiple bur, and along the flow direction of mixture, described angle a is more and more less.

As preferably, same sloping portion arranges multiple bur, and multiple bur is staggered to stretch out from sloping portion both sides.

As preferably, the length that described bur extends is L, and same sloping portion arranges multiple bur, and along the flow direction of mixture, described length L is more and more less.

As preferably, described bur is isosceles triangle, and the base of described isosceles triangle is arranged on sloping portion, and favour plate, the drift angle of described isosceles triangle is b, and same sloping portion arranges multiple bur, along the flow direction of mixture, described drift angle b is increasing.

As preferably, described bur is isosceles triangle, and the base of described isosceles triangle is arranged on sloping portion, and favour plate, the base of described isosceles triangle is S1, and same sloping portion arranges multiple bur, along the flow direction of mixture, described S1 is more and more less.

As preferably, same sloping portion arranges multiple bur, and the distance of adjacent bur is S2, and along the flow direction of mixture, described S2 is increasing.

Compared with prior art, plate type heat exchanger of the present utility model and heat exchange plate thereof have following advantage:

1) bur of punching press is applied to the plate-fin heat exchanger of azeotropic multicomponent mixture condensation by the present invention first, overcomes the problem that plate-fin heat exchanger heat exchange efficiency is low for a long time, significantly improves heat exchange efficiency.

2) on the one hand can breakable layer laminar sublayer, on the other hand compared with " punching " fin, not because heat exchange area is lost in punching, and " thorn " and " hole " can disturbance fluid on differing heights respectively, strengthens different thermal resistance links;

3) aperture that punching press " aculea " is formed, by the impact of " aculea " downstream pressure field, can realize pressure and the mass exchange of fin media of both sides, damage the stability of viscous sublayer and liquid film;

4) for the fluid of non-azeotrope multicomponent mixture, can the contact area of expansion gas-liquid interface and gas phase boundary and cooling wall be realized by " aculea " and strengthen disturbance;

5) easily process realization, manufacture difficulty and cost can not obviously rise;

6) by a large amount of experiments, the physical dimension of best plate-fin heat exchanger is determined;

7) be H by the distance of the adjacent plate of design, the length on isosceles triangle base is h, the distance of adjacent sloping portion is w, the drift angle of isosceles triangle is b, the angle of the bearing of trend of described bur and the flow direction of mixture is the change of the parameters such as a along fluid flow direction, improves heat exchange efficiency or reduces fluid pressure.

8) solve the problem that heat exchange efficiency containing on-condensible gas is low, save the energy greatly.

Accompanying drawing explanation

Fig. 1 is a kind of plate-fin heat exchanger heat exchange plate of the utility model structural representation;

Fig. 2 is the structural representation of the utility model plate wing unit;

Fig. 3 is the schematic diagram that the utility model arranges bur structures slope part planar;

Fig. 4 is another schematic diagram that the utility model arranges bur structures slope part planar;

Fig. 5 is triangle bur structural representation of the present utility model;

Fig. 6 is the tangent plane structural representation in the utility model triangle bur runner;

The structural representation that Fig. 7 the utility model bur extends to sloping portion both sides;

Fig. 8 sloping portion bur, hole affect schematic diagram to pressure and mass exchange.

Reference numeral is as follows:

1 seal, 2 fluid passages, 3 plates, 4 sloping portions, 5 drift angles, 6 burs, 7 fins.

Detailed description of the invention

Below in conjunction with accompanying drawing, detailed description of the invention of the present utility model is described in detail.

Herein, if do not have specified otherwise, relate to formula, "/" represents division, "×", " * " represent multiplication.

As shown in Figure 1, a kind of plate-fin heat exchanger for the condensation of non-azeotrope multicomponent mixture, described plate-fin heat exchanger comprises plate 3 parallel to each other, forms fluid passage 2 between described adjacent plate 3, arranges fin 7 between described adjacent plate 3.Described fin 7 comprises the sloping portion 4 tilted with plate 3, by impact style processing bur 6 on sloping portion 4, thus the fluid of sloping portion 4 both sides is communicated with by the hole that sloping portion 4 is formed by impact style; Described bur 6 stretches out from sloping portion 4.

By arranging bur 6, there is following advantage:

1) on the one hand can breakable layer laminar sublayer, on the other hand compared with " punching " fin, not because heat exchange area is lost in punching, and " thorn " and " hole " can disturbance fluid on differing heights respectively, strengthens different thermal resistance links;

2) aperture that punching press " aculea " is formed, by the impact of " aculea " downstream pressure field, can realize pressure and the mass exchange of fin media of both sides, damage the stability of viscous sublayer and liquid film;

3) for the fluid of non-azeotrope multicomponent mixture, can the contact area of expansion gas-liquid interface and gas phase boundary and cooling wall be realized by " aculea " and strengthen disturbance;

4) easily process realization, manufacture difficulty and cost can not obviously rise.

In plate-fin heat exchanger, take above-mentioned measure, the simple and easy effective technology again of non-azeotrope blending agent condensing heat-exchange can greatly be improve.With take compared with " punching " fin, the heat exchange efficiency of 20-30% can be improved.

As preferably, the angle that described bur 6 and the flow direction of mixture are formed is acute angle, as shown in Figure 8.

As preferably, as shown in Figure 2, as preferably, as shown in Figure 2, described fin 7 is triangular form fin, and described fin 7 comprises the sloping portion 4 be connected with upper and lower plate 3, forms triangle between adjacent fin and plate 3.

As shown in Figure 6, the angle of the described bearing of trend of bur 6 and the flow direction of mixture is a, and as shown in Figure 3, along the flow direction of mixture, same sloping portion 4 arranges multiple bur 6, and along the flow direction of mixture, described angle a is increasing.

Found through experiments, large by the change gradually of angle a, compared with identical with angle a, higher heat exchange efficiency can be realized, approximately can improve the heat exchange efficiency of about 10%.

As preferably, along the flow direction of mixture, it is more and more less that angle a becomes large amplitude.Found through experiments, change the amplitude that the change of angle a is large, when can ensure heat exchange efficiency, reduce flow resistance further, approximately can reduce the flow resistance of about 5%.

As preferably, the length that described bur 6 extends is L, and along the flow direction of mixture, same sloping portion 4 arranges multiple bur 6, and along the flow direction of mixture, described length L is increasing.Found through experiments, large by the change gradually of length L, compared with identical with length L, higher heat exchange efficiency can be realized, approximately can improve the heat exchange efficiency of about 9%.

As preferably, along the flow direction of mixture, it is more and more less that length L becomes large amplitude.Found through experiments, the amplitude that the change of length L is large is more and more less, when can ensure heat exchange efficiency, reduces flow resistance further, approximately can reduce the flow resistance of about 5%.

As preferably, described bur 6 is isosceles triangle, and the base of described isosceles triangle is arranged on sloping portion 4.As preferably, base is identical with the angle of inclination of sloping portion, shown in Fig. 3,4.The drift angle of described isosceles triangle is b, and along the flow direction of mixture, same sloping portion 4 arranges multiple bur 6, and along the flow direction of mixture, when base length remains unchanged, described bur drift angle b is more and more less.Found through experiments, by diminishing gradually of bur drift angle b, compared with identical with drift angle b, higher heat exchange efficiency can be realized, approximately can improve the heat exchange efficiency of about 8%.

As preferably, along the flow direction of mixture, the amplitude that drift angle b diminishes is more and more less.Found through experiments, the amplitude that drift angle b diminishes is more and more less, when can ensure heat exchange efficiency, reduces flow resistance further, approximately can reduce the flow resistance of about 4%.

As preferably, described bur 6 is isosceles triangle, and the base of described isosceles triangle is arranged on sloping portion, as preferably, base is identical with the angle of inclination of sloping portion, and the base length of described isosceles triangle is h, along the flow direction of mixture, same sloping portion 4 arranges multiple bur 6, along the flow direction of mixture, same sloping portion 4 arranges multiple bur, when drift angle remains unchanged, along the flow direction of mixture, described h is increasing.Found through experiments, large by the change gradually of h, compared with identical with h, higher heat exchange efficiency can be realized, approximately can improve the heat exchange efficiency of about 7%.

As preferably, along the flow direction of mixture, it is more and more less that h becomes large amplitude.Found through experiments, it is more and more less that h becomes large amplitude, when can ensure heat exchange efficiency, reduces flow resistance further, approximately can reduce the flow resistance of about 5%.

As preferably, along the flow direction of fluid, same sloping portion arranges many row's burs 6, and as shown in Figures 3 and 4, often the distance of arranging between bur is S2, and along the flow direction of mixture, described S2 is increasing.Why so arrange, main purpose is large by the change of S2, realizes, when ensureing heat exchange efficiency, reducing flow resistance further.Found through experiments, flow resistance reduces about 10%.

Described S2 is for calculating distance with the base of the bur of adjacent row.

As preferably, as shown in Figure 4, many row's burs 6 are shifted structure.

Find in an experiment, the distance of adjacent plate 3 can not be excessive, cross the reduction that conference causes heat exchange efficiency, too small meeting causes flow resistance excessive, in like manner, for the base length of the isosceles triangle of bur, drift angle, bur, the angle of triangular fin and the angle of fluid flow direction etc. all can not be excessive or too small, excessive or too smallly the change of the reduction of heat exchange efficiency or flow resistance all can be caused large, therefore in the distance of adjacent plate 3, the base length of isosceles triangle, drift angle, an optimized size relationship is met between the parameters such as the angle of bur and fluid flow direction.

Therefore, the utility model is thousands of numerical simulations by the heat exchanger of multiple different size and test data, meeting in industrial requirements pressure-bearing situation (below 10MPa), when realizing maximum heat exchange amount, the dimensionally-optimised relation of the heat exchange plate of the best summed up.

The triangle (i.e. triangular fin) formed between described adjacent sloping portion and plate 3 (i.e. base) is equilateral triangle, described bur is isosceles triangle, the base of described isosceles triangle is arranged on sloping portion, as preferably, base is identical with the angle of inclination of sloping portion, the distance of adjacent plate is H, and the length on isosceles triangle base is h, meets following relation:

7*h/H=c1*Ln (L*sin (a)/w)+c2, wherein 0.19<c1<0.20,0.64<c2<0.66, preferably, c1=0.1968, c2=0.6534;

Sin (b/2)=c3-c4*Ln (sin (a)), wherein=0.47<c3<0.48,0.34<c4<0.36,

Preferably, c3=0.4737, c4=0.3546;

Wherein=15 ° of <a<66 °, 55 ° of <b<165 °, H=6-14mm,

0.11<L*sin(a)/w<0.25，0.23<7*h/H<0.40；

Ln is logarithmic function;

H be with the relative face of adjacent plate between distance, namely the base mid point of equilateral triangle is to the distance of drift angle, W be with the mid point on isosceles triangle base equilateral triangle on select and be parallel to plate direction (i.e. direction, base) and extend to the distance of equilateral triangle adjacent edge, L is the distance of summit to base mid point of isosceles triangle.

Can be found out by above-mentioned formula, the drift angle of W from plate to equilateral triangle constantly diminishes, and corresponding L also constantly diminishes.

By the geometric scale of the best of " bur " that go out of above-mentioned formula, heat exchange efficiency can be improved, can realize only to viscous sublayer or comprise liquid film and to the strengthening comprising gas phase boundary different scale internal thermal resistance, avoiding measures is excessive, causes unnecessary drag losses simultaneously.

As preferably, the base of the adjacent bur of described same row all on one wire, the bur distance that same row is adjacent is S1, and described 4 × h<S1<6 × h, wherein S1 is with the distance of the mid point on the base of adjacent two isosceles triangle burs.

As preferably, the base of the isosceles triangle of the bur of adjacent row is parallel to each other, and the summit of isosceles triangle is L to the distance of base mid point, and the distance S2 of adjacent row is 4*L<S2<7*L.Be preferably S2=5*L.

When the base of the isosceles triangle of adjacent row is different, take the weighted average on two bases to calculate.

As preferably, the angle of the isosceles triangle of same row is identical with base.Namely shape is identical, is equal shape.

For formula above, for the bur that front and rear row size is different, be also still suitable for.

For the concrete dimensional parameters do not mentioned, design according to normal heat exchanger.

Along the drift angle of triangular fin towards leg-of-mutton base, the angle a of the bur extended in triangle runner is increasing.Mainly by the continuous change of angle, while guarantee improves heat exchange efficiency, flow resistance can be reduced.Because in triangle runner, the circulation area of drift angle is minimum, and the circulation area on base is maximum, therefore, the angle a arranged by the position that circulation area is little is little, can reduce flow resistance, avoids again corner position place to cause short circuit phenomenon to occur because flow resistance is excessive simultaneously.

As preferably, along the drift angle of triangular fin towards leg-of-mutton base, the amplitude that angle a increases is increasing.Found through experiments, by increasing the amplitude of angle a, the heat exchange efficiency of about about 10% can be improved, and resistance increases relatively only increase about 1%.Therefore heat exchange efficiency is greatly improved.

Along the drift angle of triangular fin towards leg-of-mutton base, the L extended in triangle runner is increasing.Mainly by the continuous change of L, while guarantee improves heat exchange efficiency, flow resistance can be reduced.Because in triangle runner, the circulation area of drift angle is minimum, and the circulation area on base is maximum, therefore, the L arranged by the position that circulation area is little is little, can reduce flow resistance, avoids again corner position place to cause short circuit phenomenon to occur because flow resistance is excessive simultaneously.

As preferably, along the drift angle of triangular fin towards leg-of-mutton base, the amplitude that L increases is increasing.Found through experiments, by increasing the amplitude of L, the heat exchange efficiency of about about 10% can be improved, and resistance increases relatively only increase about 0.8%.Therefore heat exchange efficiency is greatly improved.

As preferably, as shown in Figure 7, sloping portion is arranged multiple bur 6, described bur extends to the not homonymy of sloping portion.

As preferably, same sloping portion is arranged arranges bur more, and to arrange bur different to the extension side of sloping portion from other at least one row's bur.

As preferably, adjacent bur of often arranging extends to the not homonymy of sloping portion.

By setting like this, fluid can be made in the passage of sloping portion both sides to replace heat exchanging tampering, improve heat exchange efficiency further.With compared with the same side, can about 8% be improved.

Although the utility model discloses as above with preferred embodiment, the utility model is not defined in this.Any those skilled in the art, not departing from spirit and scope of the present utility model, all can make various changes or modifications, and therefore protection domain of the present utility model should be as the criterion with claim limited range.

Claims (10)

1. the plate-fin heat exchanger for the condensation of non-azeotrope multicomponent mixture, described plate-fin heat exchanger comprises plate parallel to each other, between described plate, fin is set, described fin comprises the sloping portion favouring plate, it is characterized in that, sloping portion processes bur by impact style.

2. plate-fin heat exchanger as claimed in claim 1, it is characterized in that, described fin is triangular form fin, and described sloping portion is connected with adjacent plate, forms triangle between adjacent sloping portion and plate.

3. plate-fin heat exchanger as claimed in claim 2, is characterized in that, along the drift angle of triangular fin towards leg-of-mutton base, the bur length L extended in triangle runner is increasing.

4. plate-fin heat exchanger as claimed in claim 3, is characterized in that, along the drift angle of triangular fin towards leg-of-mutton base, the amplitude that L increases is increasing.

5. plate-fin heat exchanger as claimed in claim 1 or 2, it is characterized in that, described bur is isosceles triangle, and the base of described isosceles triangle is arranged on sloping portion.

6. plate-fin heat exchanger as claimed in claim 1 or 2, it is characterized in that, sloping portion is arranged arranges bur more, and the bur of described adjacent row is stagger arrangement distribution.

7. plate-fin heat exchanger as claimed in claim 1 or 2, it is characterized in that, sloping portion is arranged multiple bur, described bur extends to the not homonymy of sloping portion.

8. plate-fin heat exchanger as claimed in claim 1 or 2, it is characterized in that, sloping portion is arranged arranges bur more, and adjacent row's bur extends to the not homonymy of sloping portion.

9. plate-fin heat exchanger as claimed in claim 1 or 2, it is characterized in that, sloping portion is arranged arranges bur more, and along the flow direction of mixture, the distance of often arranging between bur is increasing.

10. plate-fin heat exchanger as claimed in claim 2, it is characterized in that, it is equilateral triangle that sloping portion and plate form triangle, described bur is isosceles triangle, the base of described isosceles triangle is arranged on sloping portion, and the length on isosceles triangle base is h, and the drift angle of isosceles triangle is b, the angle of the bearing of trend of described bur and the flow direction of mixture is a, meets following formula:

7*h/H=c1*Ln (L*sin (a)/w)+c2, wherein 0.19<c1<0.20,0.64<c2<0.66,

Sin (b/2)=c3-c4*Ln (sin (a)), wherein=0.47<c3<0.48,0.34<c4<0.36;

Wherein=15 ° of <a<66 °, 55 ° of <b<165 °, H=6-14mm;

Wherein Ln is logarithmic function;

0.11<L*sin(a)/w<0.25，0.23<7*h/H<0.40；

H be with the relative face of adjacent plate between distance, W is being parallel to plate direction and is extending to the distance of equilateral triangle adjacent edge with the mid point on isosceles triangle base selecting on equilateral triangle, and L is the distance of summit to base mid point of isosceles triangle.