CN2453380Y - Stack-type air heat exchanger - Google Patents

Abstract

The utility model relates to a stack-type air heat exchanger. The utility model discloses heat exchange units which are provided with a heat exchange plate, the edge of the heat exchange plate is provided with a wall and a fixture, the heat exchange units which are sequentially overlapped layer-by-layer are arranged in the fixture, two crossed air ducts without mutual interference integrally are arranged in the fixture after overlapped, and the air ducts are composed of smaller ducts which are communicated. When one face of the heat exchange plate of the heat exchange units is in an integral air duct, the other face must be in the other integral air duct. The utility model has the advantages of high thermal efficiency, simple structure, and easy manufacturing; the utility model is more applicable to super thin coil materials and plates.

Description

Stacked air heat exchanger

The utility model relates to air heat exchanger.

Existing air heat exchanger has dynamic inertia formula, the metal tube of arranged radially board-like, intersection is stacked and the hollow cylinder sleeve type.Stacked and the hollow cylinder sleeve type of wherein intersecting has high heat exchanger effectiveness, but difficulty of processing is bigger.

The purpose of this utility model provides a kind of stacked air heat exchanger, has high heat exchanger effectiveness, and simple structure is easy to processing, more applicable to the thin coiled material of spy, sheet material.

Technical solution of the present utility model is, heat exchange unit is arranged, heat exchange unit has a heat exchanger plate, on the heat exchanger plate edge, wall is arranged, a fixture is arranged, the heat exchange unit of closed assembly is layer by layer arranged in fixture in order, and when the heat exchanger plate one face of forming air duct, the heat exchange unit of two non-interfering intersections of integral body by the passage aisle of each perforation in the fixture behind the closed assembly was in the integrated air passage, another face must be in another integrated air passage.

The above heat exchanger plate is a surface plate, or the plate of concaveconvex shape.

Have a pair of equidirectional wall on the symmetrical edge of heat exchanger plate of the present utility model at least, a wall is perhaps arranged on another edge, the heat exchanger plate back side simultaneously.

There is wall at above the utility model heat exchanger plate edge, perhaps also has supporting plate on the wall.

The utility model fixture is a framework, or one the two pairs casees that connect the air port.

Above the utility model heat exchange unit closed assembly is the folded mutually of metope between the heat exchange unit or wall limit, or supporting plate folded mutually of wall between the heat exchange unit, or the folding mutually of the supporting plate of the wall limit of a heat exchange unit and the wall of another heat exchange unit.

It is folded mutually that the wall of heat exchange unit of the present utility model and adjacent cells heat exchanger plate do not have an edge of wall, or do not had the folding mutually an of edge of wall by the supporting plate of the wall of heat exchange unit and adjacent cells heat exchanger plate.

Framework of the present utility model is a hexahedron, and wherein four faces connect corresponding to two integrated air passages.

More than two non-interfering integrated air passages of the present utility model, its in the position in space arbitrarily and intersect, the geometry of heat exchange unit and size, the geometry of wall, supporting plate and size all can be chosen arbitrarily.

Operation principle of the present utility model is: when the air draught of two bursts of different temperatures during respectively through two non-interfering integrated air passages, realized that by the heat-exchange surface that is in the heat exchange unit in the passage air of two bursts of different temperatures carries out heat exchange.The utility model can be used in the air heat exchanger product in airless source, have air flow source as in the two-way exchange type ventilator, have in the products such as air regulator of air flow source.Its effect is to make the fresh air of suction fully carry out heat exchange in the utility model, reclaims cold or heat in the foul atmosphere of discharging from air conditioner surroundings, has obvious energy-saving effect.

The utility model has the advantages that to have high heat exchanger effectiveness, simple structure is easy to processing, also applicable to the thin coiled material of spy, sheet material.

Below in conjunction with accompanying drawing embodiment of the present utility model is described:

Fig. 1 heat exchange unit organigram of the present utility model;

Fig. 2 the utility model heat exchange unit A-A profile construction schematic diagram;

Fig. 3 the utility model heat exchange unit D structure schematic diagram;

Fig. 4 the utility model is used for the belfry schematic diagram of closed assembly heat exchange unit;

The schematic diagram of constructing behind Fig. 5 the utility model heat exchange unit closed assembly;

Fig. 6 heat exchanger plate of the present utility model has the organigram of equidirectional wall with the two symmetrical minor faces of one side;

Fig. 7 the utility model heat exchanger plate has the organigram of equidirectional wall with the two symmetrical long limits of one side;

Fig. 8 the utility model is used for the belfry schematic diagram that closed assembly has the heat exchange unit of two minor face walls;

Organigram behind Fig. 9 the utility model heat exchange unit closed assembly;

Figure 10 heat exchange unit blade position of the present utility model, organigram;

Figure 11 the utility model is used for the belfry schematic diagram of closed assembly square heat exchange unit;

Figure 12 the utility model has organigram behind the heat exchange unit closed assembly of supporting plate;

Wall mounting plate position, Figure 13 the utility model heat exchange unit heat exchanger plate coplanar symmetry two edge, organigram;

Figure 14 the utility model is used for the closed assembly heat exchanger unit two pairs of organigrams that connect the ventilating opening case.

Embodiment one:

Shown in Fig. 1,2,3,4,5, the utility model is formed just like heat exchange unit shown in Fig. 1,2,3 and framework shown in Figure 4.Heat exchanger plate is a square, and its heat exchange unit is configured as: on a symmetrical edge of heat exchanger plate 3 equidirectional wall 1 is arranged; The equidirectional wall 2 opposite with wall 1 direction arranged on another symmetrical edge, the heat exchanger plate back side.Unit shown in Figure 1 is put into the base of frame of direction shown in Figure 4, again unit shown in Figure 2 is put into direction framework shown in Figure 4 and closed assembly on following unit, wall 2 is folded mutually with 1 on the wall of lower unit, alternately adorn unit illustrated in figures 1 and 2 then as stated above to finishing.At this moment, the structure behind the heat exchange unit closed assembly in framework has obtained a complete stacked air heat exchanger as shown in Figure 5.From as can be known shown in Figure 5, totally 6 passage aisles of the positive even level of counting has from bottom to top been formed an integrated air passage of this direction; Equally, totally 6 passage aisles of the odd-level of counting from bottom to top from the right side has been formed another integrated air passage of this direction, the wall of heat exchange unit is folded mutually the effect that stops that this direction air flows into, reach that two integrated air passages do not disturb mutually, when heat exchanger plate 3 one face of heat exchange unit are in the integral passage, another face must be in purpose in another integrated air passage, when the air draught of two bursts of different temperatures passes through above-mentioned two non-interfering integrated air passages respectively, promptly finish the heat exchange of two strands of air by heat exchange unit.Framework of the present utility model is a hexahedron, and wherein four faces connect corresponding to two integrated air passages.

Embodiment two:

Shown in Fig. 6,7,8,9, the utility model is formed just like Fig. 6, heat exchange unit shown in Figure 7 and framework shown in Figure 8.Heat exchanger plate is a rectangle, and its heat exchange unit is configured as: as shown in Figure 6, equidirectional wall 2 is arranged on a pair of edge of heat exchanger plate 3 minor faces; As shown in Figure 7, on a pair of edge on heat exchanger plate 3 long limits, equidirectional wall 2 is arranged.Unit shown in Figure 6 is put into the base of frame of direction shown in Figure 8, again unit shown in Figure 7 is put on the framework of direction shown in Figure 8 and the unit of closed assembly below being in, its two walls fold two edges in addition that do not have wall in the upper surface of heat exchanger plate 3, then as stated above alternately closed assembly Fig. 6 and unit shown in Figure 7 to finishing.At this moment, heat exchange unit structure behind the closed assembly in framework has obtained a complete stacked air heat exchanger as shown in Figure 9.From as can be known shown in Figure 9, totally 3 passage aisles of the positive odd-level of counting has from bottom to top been formed this direction and an integrated air passage; Equally, totally 3 passage aisles of the even level of counting from bottom to top from the right side has been formed another integrated air passage of this direction, the wall of heat exchange unit has the effect that stops that this direction air flows into, reach that two integrated air passages do not disturb mutually, when heat exchanger plate 3 one face of heat exchange unit are in the integral passage, another face must be in purpose in another integrated air passage, when the air draught of two bursts of different temperatures passes through above-mentioned two non-interfering integrated air passages respectively, promptly finish the heat exchange of two strands of air by heat exchange unit.

Embodiment three:

Shown in Figure 10,11,12, the utility model is made up of as shown in figure 10 heat exchange unit and framework shown in Figure 11.Heat exchanger plate is a square, and its heat exchange unit is configured as: equidirectional wall 2 is being arranged on a pair of edge of heat exchanger plate 3 bottom surfaces, wall 1 is arranged on another edge of upper surface and the supporting plate 4 of wall 1 is arranged.Unit shown in Figure 10 is put into the base of frame of direction shown in Figure 11, again with unit shown in Figure 10 left or right turn over put into behind the turnback angle direction framework shown in Figure 11 and closed assembly on following unit, each is folded mutually with heat exchanger plate 3 to make two supporting plates 4, again unit shown in Figure 10 is put into the framework of direction shown in Figure 11 and closed assembly on following unit, make folding mutually of the folded mutually or wall limit of 2 on the wall of wall 2 and lower unit, alternately adorn unit shown in Figure 10 then as stated above to finishing.At this moment, the structure behind the heat exchange unit closed assembly in framework has obtained a complete stacked air heat exchanger as shown in figure 12.From as can be known shown in Figure 12, totally 6 passage aisles of the positive even level of counting has from bottom to top been formed an integrated air passage of this direction; Equally, totally 6 passage aisles of the odd-level of counting from bottom to top from the right side has been formed another integrated air passage of this direction, the wall of heat exchange unit is folded mutually the effect that stops that this direction air flows into, reach that two integrated air passages do not disturb mutually, another face must be in purpose in another integrated air passage when heat exchanger plate 3 one face of heat exchange unit were in the integral passage, when the air draught of two bursts of different temperatures passes through above-mentioned two non-interfering integrated air passages respectively, promptly finish the heat exchange of two strands of air by heat exchange unit.

Embodiment four:

With embodiment one, just regular or irregular concaveconvex shape structure on the plane of heat exchanger plate 3 can enlarge heat-exchange surface, thereby improve heat exchange effect.

Embodiment five:

With embodiment one, just the closed assembly of heat exchange unit is the folded mutually of wall limit between the heat exchange unit.

Embodiment six:

With embodiment one, the closed assembly that is heat exchange unit is that the supporting plate of wall between the heat exchange unit is folded mutually.

Embodiment seven:

With embodiment two, the closed assembly that is heat exchange unit is that the metope of heat exchange unit is folded mutually with two limits that adjacent cells does not have wall.

Embodiment eight:

With embodiment two, just the closed assembly of heat exchange unit as shown in figure 13, its closed assembly is to be folded mutually with two edges of the no wall of adjacent cells heat exchanger plate by the supporting plate of wall.

Embodiment nine:

With embodiment one, just fixture as shown in figure 14, case is a hexahedron, wherein four faces connect corresponding to two integrated air passages, promptly are the casees that two pairs of perforation air ports are arranged.

Claims (8)

1, stacked air heat exchanger, it is characterized in that heat exchange unit is arranged, heat exchange unit has heat exchanger plate, on the heat exchanger plate edge, wall is arranged, a fixture is arranged, the heat exchange unit of closed assembly is layer by layer arranged in fixture in order, form the air duct of two non-interfering intersections of integral body in the fixture behind the closed assembly by the passage aisle of each perforation, when the heat exchanger plate one face of heat exchange unit was in an integrated air passage, another face must be in another integrated air passage.

2, stacked air heat exchanger according to claim 1 is characterized in that heat exchanger plate is a surface plate, or the plate of concaveconvex shape.

3, stacked air heat exchanger according to claim 1 is characterized in that having a pair of equidirectional wall at least on the symmetrical edge of heat exchanger plate, and a wall is perhaps arranged on another edge, the heat exchanger plate back side simultaneously.

4, according to claim 1 or 3 described stacked air heat exchangers, it is characterized in that there is wall at the heat exchanger plate edge, perhaps also have supporting plate on the wall.

5, stacked air heat exchanger according to claim 1 is characterized in that fixture is a framework, or one has two pairs of casees that connect the air port.

6, stacked air heat exchanger according to claim 1, it is characterized in that the heat exchange unit closed assembly is the folded mutually of metope between the heat exchange unit or wall limit, or supporting plate folded mutually of wall between the heat exchange unit, or the folding mutually of the supporting plate of the wall limit of a heat exchange unit and the wall of another heat exchange unit.

7, stacked air heat exchanger according to claim 1, the wall that it is characterized in that heat exchange unit is folded mutually with the edge that the adjacent cells heat exchanger plate does not have wall, or is not had the folding mutually an of edge of wall by the supporting plate of the wall of heat exchange unit and adjacent cells heat exchanger plate.

8, stacked air heat exchanger according to claim 5 is characterized in that framework or case are hexahedrons, and wherein four faces connect corresponding to two integrated air passages.

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