JP2016047967A - Aluminium alloy flat tube for heat exchanger and method for manufacturing the same, and heat exchanger core and method for manufacturing the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide: an aluminium alloy flat tube for heat exchangers, capable of obtaining a heat exchanger excellent in corrosion resistance even when a brazing heating time is reduced in order to improve the mass productivity of the heat exchanger; a method for manufacturing the aluminium alloy flat tube for heat exchangers; the heat exchanger excellent in corrosion resistance; and a method for manufacturing the heat exchanger.SOLUTION: The method for manufacturing the aluminium alloy flat tube for heat exchangers comprises: superimposing the flat surface of a Zn sprayed element tube having a Zn sprayed layer of 5-20 g/mon the flat surface of an extruded flat tube formed of aluminium alloy consisting of Cu of 0.1-0.7 mass% and the remainder of aluminum and inevitable impurities; and performing a preliminary diffusion heat treatment so that the maximum arrival temperature is 430-550°C, and the total diffusion amount of Zn ΣDt shown in the following formula (1) is in a range of 0.8×10to 4.6×10(m). ΣDt=ΣD×exp (-Q/(R-Tn))×Δtn (1).SELECTED DRAWING: Figure 8

Description

  The present invention is an aluminum alloy flat tube for a heat exchanger for manufacturing a heat exchanger core by brazing in combination with a fin, an aluminum alloy flat tube for a heat exchanger having a zinc diffusion layer on the outer surface side, and a method for manufacturing the same About. The present invention also relates to a method for producing a heat exchanger core using the aluminum alloy flat tube for heat exchanger of the present invention and the aluminum alloy flat tube for heat exchanger obtained by the method, and a heat exchanger obtained by the production method. Concerning the core.

  In general parallel flow type aluminum alloy heat exchangers for air conditioners, a plurality of tubes (tubes) serving as a passage for working fluid (refrigerant) for exchanging heat are arranged in parallel on the inner surface, and between these tubes. The fin is joined so as to be in contact with the tube, and is composed of a member such as a header tank or piping. A heat exchanger is manufactured by assembling these members and brazing them together. When an extruded flat multi-hole tube made of aluminum or an aluminum alloy is used as the tube material of such a heat exchanger, it is known that zinc is sprayed on the surface of the extruded flat tube as an anticorrosion treatment. The zinc diffused from the surface layer of the extruded flat multi-hole tube to the inside during brazing heating forms a zinc diffusion layer in the surface layer portion of the extruded multi-hole flat tube, and the zinc diffusion layer is the extruded flat multi-hole tube. In order to suppress the pitting corrosion of the extruded multi-hole tube in order to exert the sacrificial anode effect and to exhibit the effect as an anticorrosive layer of the extruded flat multi-hole tube. , Has improved corrosion resistance.

  The method of spraying zinc on the surface of an aluminum extruded flat multi-hole tube is to apply two high-voltage currents by bringing two zinc wires close to each other, arc discharge between the zinc wires, the tip of the zinc wire melts, This is a method in which molten zinc is blown off by blowing an inert gas, and the molten zinc is adhered to the surface of the extruded multi-hole tube by passing through the extruded multi-hole tube made of aluminum. As the zinc wire is sequentially sent as it melts, the arc discharge can be continued, so that a uniform zinc sprayed layer can be formed on the surface of the long extruded flat multi-hole tube. A long extruded flat multi-hole tube on which a zinc sprayed layer is formed is wound in a single coil or aligned in a coil shape, or is cut into a predetermined size and bundled with a straight material.

  Here, in the manufacture of heat exchangers in recent years, it is required to shorten the brazing heating time in order to increase mass productivity. When the brazing heating time is shortened, the zinc diffusion amount is decreased, so that the zinc concentration on the surface of the extruded multi-hole tube is increased and the zinc diffusion layer is thinned. Therefore, the thickness of the zinc diffusion layer is reduced, causing a problem that sufficient corrosion resistance cannot be obtained.

  Therefore, as a method of forming a zinc diffusion layer having a stable sacrificial anode effect, Japanese Patent Application Laid-Open No. 2007-528297 (Patent Document 1) discloses that a Zn sprayed aluminum tube is placed in an inert gas atmosphere before the brazing step. A method of performing brazing after performing Zn diffusion treatment by heating is described.

JP 2007-528297 A (Claims)

However, in the method of Patent Document 1, Zn diffusion treatment is performed at 470 to 620 in an inert gas atmosphere.
Although it is disclosed that the heat treatment is performed at 5 ° C. for 5 minutes to 10 hours, in order to shorten the heating time and improve the production efficiency, it is efficient to raise the heating temperature. Then, the sprayed Zn is easily oxidized. In order to prevent such deterioration due to oxidation, heating in an inert gas atmosphere is required. And in order to heat in inert gas atmosphere, in addition to preparing an inert gas, since the heating furnace with a sealing property is needed, it becomes a cost increase factor. Also, if inert gas leaks, there is a danger of suffocation.

  Also, when using fins that are corrugated brazing sheet clad with brazing material on both sides of the core material, the zinc on the surface of the flat tube is mixed with the solder melted by brazing heating, forming a fillet with a high zinc concentration Will do. Then, since a fillet becomes easy to corrode, the problem that a fin will peel off early arises.

  Therefore, in order to reduce the surface zinc concentration after zinc diffusion, it is conceivable to reduce the amount of sprayed zinc. To that end, however, the current of the arc discharge is reduced or the feeding speed of the zinc wire is reduced. It is possible. However, in any case, since the discharge becomes unstable, there is a problem that it is difficult to stably maintain the thermal spraying, and thus there is a problem that it is difficult to reduce the thermal spraying amount. Also, when the amount of sprayed zinc is lowered, the zinc particles adhering to the surface of the extruded multi-hole tube become sparse, and there are many places where aluminum is exposed without the zinc particles adhering, and a uniform zinc diffusion layer can be formed. The problem of disappearing also arises.

  Furthermore, since the sprayed zinc partially evaporates during brazing heating, reducing the amount of sprayed zinc has led to a decrease in the corrosion resistance of the flat tube.

  Because of these problems, a certain amount of zinc must be sprayed. Therefore, when shortening the brazing heating time in order to improve the mass productivity of the heat exchanger, The zinc concentration on the surface was high, and the early peeling of the fins was likely to occur.

  Therefore, an object of the present invention is to provide an aluminum alloy flat tube capable of obtaining a heat exchanger with good corrosion resistance even when the brazing heating time is shortened in order to improve the mass productivity of the heat exchanger, a manufacturing method thereof, and An object of the present invention is to provide a heat exchanger core having good corrosion resistance and a manufacturing method thereof at low cost.

  As a result of intensive studies to solve the above-mentioned problems, the inventors of the present invention have found that a flat surface of a zinc sprayed element tube in which a zinc sprayed layer having a specific amount of spraying is provided on the flat surface of an aluminum alloy flat tube. An aluminum alloy flat tube capable of obtaining a heat exchanger with good corrosion resistance can be obtained by performing pre-diffusion heat treatment in which the surfaces are overlapped and heated so that the total diffusion amount of zinc is in a specific range. The present invention has found that a heat exchanger having good corrosion resistance can be obtained by brazing and heating such that the aluminum alloy flat tube is used and the total amount of zinc diffusion is in a specific range. It came to complete.

That is, the present invention (1) contains 0.1 to 0.7% by mass of Cu, and 5 to 20 g / m ² of zinc on the flat surface of an aluminum alloy flat tube made of the balance aluminum and inevitable impurities. The flat surfaces of the zinc sprayed element tube provided with the thermal spray layer are overlapped with each other, the maximum reached temperature is 430 to 550 ° C., and the total diffusion amount ΣDt of zinc shown in the following formula (1) is 0.8 × 10 ⁻⁹ to 4 The present invention provides a method for producing an aluminum alloy flat tube for a heat exchanger, characterized by performing a pre-diffusion heat treatment for heating to a range of 6 × 10 ⁻⁹ (m ² ).
ΣDt = ΣD ₀ · exp (−Q / (R · Tn)) · Δtn (1)
(In the formula, Tn represents the total heating time from the time when the pre-diffusion heating is started and the temperature reaches 200 ° C. to the time when the pre-diffusion heating is finished and the temperature reaches 200 ° C. ) Is the temperature (K) of each minute time when divided by), D ₀ is 1.77 × 10 ⁻⁵ (m ² / s), Q is 117000 (kJ / mol), R Is 8.3145 (J / mol · K).)

The present invention (2) is a flat tube formed of an aluminum alloy,
The aluminum alloy part contains 0.1 to 0.7% by mass of Cu and Zn, and is an aluminum alloy composed of the remaining aluminum and inevitable impurities,
Zinc is diffused from the outer edge of the aluminum alloy part to a position at a depth of 95 to 250 μm, and the zinc concentration on the surface of the flat surface of the aluminum alloy part is 1.5 to 15%, An aluminum alloy flat tube for a heat exchanger is provided.

Moreover, this invention (3) obtains the aluminum alloy flat tube for heat exchangers by the manufacturing method of the aluminum alloy flat tube for heat exchangers of this invention (1), Then, the obtained aluminum alloy flat tube for heat exchangers, A heat exchanger core in which an aluminum alloy brazing fin material clad with an Al—Si brazing material on both sides of an Al—Mn alloy is combined with a total diffusion amount of zinc in the pre-diffusion heat treatment, and the heat Heating at a temperature and time such that the total diffusion amount of zinc shown in the following formula (2) in brazing heating of the exchanger core is in the range of 2 × 10 ^{−9 to} 5 × 10 ⁻⁹ m ^2. The present invention provides a method for manufacturing a heat exchanger core, characterized by performing brazing heat treatment.
ΣDt = ΣD ₀ · exp (−Q / (R · Tn)) · Δtn (2)
(In the formula, Tn represents the total heating time from the time when the brazing heating is started and the temperature reaches 200 ° C. until the temperature reaches 200 ° C. ) Is the temperature (° C.) of each minute time when divided by), D ₀ is 1.77 × 10 ⁻⁵ (m ² / s), Q is 117000 (kJ / mol), R Is 8.3145 (J / mol · K).)

  Moreover, this invention (4) provides the heat exchanger core obtained by performing the manufacturing method of the heat exchanger core of this invention (3).

  ADVANTAGE OF THE INVENTION According to this invention, even if it shortens brazing heating time in order to improve the mass-productivity of a heat exchanger, the aluminum alloy flat tube which can obtain a heat exchanger with favorable corrosion resistance, its manufacturing method, and corrosion resistance are A good heat exchanger core and a manufacturing method thereof can be provided at a low cost.

It is a typical perspective view which shows the example of a form of the flat multi-hole tube made from an aluminum alloy before a zinc sprayed layer is formed. It is sectional drawing of the flat multi-hole tube made from the aluminum alloy of FIG. It is typical sectional drawing which shows the example of a form of a zinc spraying element pipe | tube. It is a schematic diagram which shows a mode that the flat surfaces of a zinc spraying element pipe | tube are piled up. It is a schematic diagram which shows a mode that the flat surfaces of a zinc spraying element pipe | tube are piled up. It is a schematic diagram which shows a mode that the flat surfaces of a zinc spraying element pipe | tube are piled up. It is a typical perspective view which shows the example of a form of the aluminum alloy flat tube for heat exchangers of this invention. It is sectional drawing of the aluminum alloy flat tube for heat exchangers of FIG. It is a typical graph which shows a heat pattern. It is typical sectional drawing which shows a part of form example of the aluminum alloy flat tube for heat exchangers of this invention. It is sectional drawing which shows the extrusion flat tube made from the aluminum alloy produced in the Example and the comparative example.

The manufacturing method of the aluminum alloy flat tube for heat exchangers of this invention contains 0.1-0.7 mass% Cu, and the flat surface of the flat tube of the aluminum alloy which consists of remainder aluminum and an unavoidable impurity WHEREIN: The flat surfaces of the zinc sprayed tubes provided with a zinc sprayed layer of 20 g / m ² are superposed, the maximum temperature reached is 430 to 550 ° C., and the total amount of zinc diffusion ΣDt represented by the following formula (1) is 0.8. × a 10 -9 ^{to 4.6} × 10 ^-9 method of manufacturing a heat exchanger aluminum alloy flat tubes, characterized in that the preliminary diffusion heat treatment of heating to be in the range of m ^2.
ΣDt = ΣD ₀ · exp (−Q / (R · Tn)) · Δtn (1)
(In the formula, Tn represents the total heating time from the time when the pre-diffusion heating is started and the temperature reaches 200 ° C. to the time when the pre-diffusion heating is finished and the temperature reaches 200 ° C. ) Is the temperature (° C.) of each minute time when divided by), D ₀ is 1.77 × 10 ⁻⁵ (m ² / s), Q is 117000 (kJ / mol), R Is 8.3145 (J / mol · K).)

  The manufacturing method of the aluminum alloy flat tube for heat exchangers of this invention is demonstrated with reference to FIGS. FIG. 1 is a schematic perspective view showing a form example of a flat multi-hole tube made of an aluminum alloy before a zinc sprayed layer is formed. FIG. 2 is a sectional view of the flat multi-hole tube made of the aluminum alloy of FIG. FIG. 3 is a schematic cross-sectional view showing an example of the form of a zinc sprayed element tube. 4 to 6 are schematic views showing a state in which the flat surfaces of the zinc sprayed element tubes are overlapped with each other, and FIG. 4 is a perspective view of the zinc sprayed element tube before the flat surfaces are overlapped with each other. These are the side views which looked at the zinc sprayed element pipe | tube before overlapping flat surfaces from the direction of the code | symbol B in FIG. 3, FIG. 6 shows the zinc sprayed element tube after overlapping flat surfaces. FIG. 4 is a side view as seen from the direction of reference sign B in FIG. FIG. 7 is a schematic perspective view showing a form example of an aluminum alloy flat tube for a heat exchanger according to the present invention. 8 is a cross-sectional view of the aluminum alloy flat tube for heat exchanger of FIG. FIG. 9 is a schematic graph showing a heat pattern.

  First, a zinc sprayed element tube that is pre-diffusion heated in the pre-diffusion heating process according to the method for manufacturing an aluminum alloy flat tube for heat exchanger of the present invention will be described.

  A zinc sprayed element tube is obtained by spraying zinc on a flat tube made of an aluminum alloy. The flat multi-hole tube 1 made of aluminum alloy shown in FIGS. 1 and 2 is a flat multi-hole tube made of aluminum alloy before the zinc sprayed layer is formed. This flat multi-hole tube 1 made of an aluminum alloy is an extruded product obtained by extruding an aluminum alloy in the tube axis direction (the direction indicated by the symbol A in FIG. 1). The flat multi-hole tube 1 made of aluminum alloy has two flat surfaces 2 that are substantially parallel to each other. In the flat multi-hole tube 1 made of aluminum alloy, a plurality of holes 4 are formed in the tube axis direction.

Next, as shown in FIG. 3, zinc sprayed layer 5 is provided by spraying zinc on flat surface 2 of flat multi-hole tube 1 made of aluminum alloy, and zinc sprayed layer 5 is formed on the surface of aluminum alloy portion 3. A zinc sprayed element tube 6 is obtained. The amount of zinc sprayed on the zinc sprayed element tube 6 is 5 to 20 g / m ² .

In the pre-diffusion heat treatment, as shown in FIGS. 4 to 6, a plurality of zinc sprayed element tubes 6 are laminated such that the flat surfaces 7 of the zinc sprayed element tubes are overlapped with each other. It is heated at ˜550 ° C. so that the total diffusion amount ΣDt of zinc shown in the formula (1) is in the range of 0.8 × 10 ^{−9 to} 4.6 × 10 ⁻⁹ m ² .

  In this way, by performing the pre-diffusion heat treatment, the zinc in the zinc sprayed layer 5 of the zinc sprayed element tube 6 is diffused into the aluminum alloy part 3, and as shown in FIGS. An aluminum alloy flat tube 11 for a heat exchanger having a zinc diffusion layer 15 is obtained on the flat surface 12 side of the aluminum alloy portion 13 having the shape shown in FIG. 7 and 8, the zinc diffusion layer 15 is shown in black in FIG. 7 and FIG. 8, but the zinc diffusion layer 15 is an aluminum alloy containing zinc diffused from the zinc sprayed layer.

  In the pre-diffusion heating treatment according to the method for producing an aluminum alloy flat tube for a heat exchanger of the present invention, the zinc sprayed element tube to be pre-diffusion heated is formed on two substantially parallel flat surfaces of the flat tube made of aluminum alloy, It is an aluminum alloy flat tube provided with a sprayed layer. That is, the zinc sprayed element tube is composed of an aluminum alloy part having a flat tube shape and a zinc sprayed layer.

  The aluminum alloy forming the aluminum alloy part of the zinc sprayed element tube (hereinafter also referred to as aluminum alloy A) contains 0.1 to 0.7% by mass of Cu, and consists of the balance aluminum and inevitable impurities.

  The Cu content of the aluminum alloy A is 0.1 to 0.7% by mass. Cu in the aluminum alloy increases the strength of the flat tube. If the Cu content of the aluminum alloy A is less than the above range, the effect of improving the strength by Cu becomes insufficient, and if it exceeds the above range, the extrudability of the flat tube is lowered.

  The aluminum alloy A can further contain one or two of 0.1 to 1.2% by mass of Si and 0.1 to 1.8% by mass of Mn.

  Si in the aluminum alloy increases the strength of the flat tube. The Si content of the aluminum alloy A is 0.1 to 1.2% by mass. If the content of Si in the aluminum alloy A is less than the above range, the effect of improving the strength by Si becomes insufficient, and if it exceeds the above range, the melting point of the flat tube is lowered and brazing is difficult. Become.

  Mn in the aluminum alloy increases the strength of the flat tube. The Mn content of the aluminum alloy A is 0.1 to 1.8% by mass. If the content of Mn in the aluminum alloy A is less than the above range, the effect of improving the strength by Mn becomes insufficient, and if it exceeds the above range, a coarse compound is produced, and the extrudability is lowered.

  Aluminum alloy A further includes one or two of 0.01 to 0.3% by mass of Cr, 0.01 to 0.3% by mass of Zr, and 0.01 to 0.3% by mass of Ti. The above can be contained.

  Cr, Zr, and Ti in the aluminum alloy coarsen the crystal grain size after brazing and improve brazing properties. If the content of Cr, Zr, Ti in the aluminum alloy A is less than the above range, the effect of Cr, Zr, Ti will be insufficient, and if it exceeds the above range, a coarse compound is produced and the extrudability decreases. .

  An aluminum alloy part, that is, a flat tube made of an aluminum alloy is usually obtained by extruding an aluminum alloy. An aluminum alloy part, that is, a flat tube made of an aluminum alloy is usually a multi-hole tube having a plurality of holes extending in the tube axis direction. The number of holes formed in the aluminum alloy part is not particularly limited.

A zinc sprayed element tube is obtained by spraying zinc on two flat surfaces of an aluminum alloy part, that is, an aluminum alloy flat tube to form a zinc sprayed layer. The method for thermally spraying is not particularly limited, and a conventional zinc spraying method can be appropriately used. As a strand used for thermal spraying, a pure zinc wire is preferably used because it is easy to manufacture.

The zinc amount of the zinc sprayed layer provided in the zinc sprayed element tube is 5 to 20 g / m ² , preferably 13 to 20 g / m ² , and particularly preferably 15 to 20 g / m ² . When the amount of zinc in the zinc sprayed layer provided in the zinc sprayed element tube is in the above range, penetration corrosion is less likely to occur and the corrosion resistance of the heat exchanger core is enhanced. On the other hand, even if the zinc amount of the zinc sprayed layer provided in the zinc sprayed element tube is less than the above range or exceeds the above range, the corrosion resistance of the heat exchanger core is lowered.

  In the pre-diffusion heat treatment, heating is performed in a state where the flat surfaces of the zinc sprayed element tubes are overlapped with each other. By heating in a state where the flat surfaces of the zinc sprayed element tube are overlapped, zinc is hardly evaporated during the pre-diffusion heat treatment. As shown in FIGS. 4 to 6, as the form in which the flat surfaces of the zinc sprayed element tubes are overlapped, a plurality of zinc sprayed tubes having straight (straight) tube axes are prepared. The present invention is not limited to the form in which the flat surfaces are stacked and laminated, and any form in which the flat surfaces of the zinc sprayed tubes are overlapped may be used. As another form, there is a form in which one long zinc sprayed tube is wound in a row or aligned in a coil shape so that the flat surfaces overlap each other. Moreover, the form wound up at coil shape at random is also possible.

  In the pre-diffusion heat treatment, a zinc spray tube in which flat surfaces are overlapped is heated at 430 ° C. to 550 ° C. In other words, heating is performed at a maximum attained temperature of 430 to 550 ° C. And, in a state where the flat surfaces of the zinc sprayed element tube are overlapped with each other, by performing heat treatment at a maximum attained temperature of 430 to 550 ° C., zinc can be efficiently diffused while suppressing evaporation of zinc. The amount of zinc sprayed is efficiently diffused from the surface of the flat surface of the flat tube to the inside. If the maximum temperature is less than 430 ° C, it takes too much time for diffusion, and it is not economical. If it exceeds 550 ° C, the amount of zinc evaporation becomes too large, and the formation of a zinc diffusion layer is insufficient. It becomes. It is particularly preferable that the maximum temperature achieved in the pre-diffusion heat treatment is 430 or higher and lower than 470 ° C., from which zinc evaporation can be further suppressed.

  In the preliminary diffusion heat treatment, the residual amount of zinc is preferably 80% by mass or more, and particularly preferably 85% by mass or more. If the remaining amount of zinc is less than the above range, the amount of sprayed zinc evaporation will increase, so the efficiency will be low, and the zinc adhering to the furnace wall will fall inadvertently due to vibration, etc. Therefore, the frequency of work for removing zinc adhering to the furnace inner wall increases. In the present invention, the remaining amount (mass%) of zinc in the pre-diffusion heat treatment is a reserve for the zinc mass (that is, the amount of sprayed zinc) of the zinc sprayed layer of the zinc sprayed element tube before the pre-diffusion heat treatment. It is the mass ratio (%) of zinc in the aluminum alloy flat tube for heat exchangers after the diffusion heat treatment.

If the zinc sprayed element tubes are separated from each other and subjected to the preliminary diffusion heat treatment, the amount of zinc evaporated during the preliminary diffusion heat treatment increases. When the maximum attained temperature in the pre-diffusion heat treatment is relatively high, if the flat surfaces of the zinc sprayed element tube are not overlapped, the evaporation of zinc is remarkably increased. Therefore, when the maximum temperature reached in the pre-diffusion heat treatment is relatively high, there arises a problem that the evaporation of zinc becomes very large. In addition, when the maximum temperature reached in the pre-diffusion heat treatment is relatively low, if the flat surfaces of the zinc sprayed element tubes are not overlapped, the amount of zinc vaporization is not as high as when the maximum temperature reached is relatively high. Although it evaporates. In general, the pre-diffusion heat treatment is performed by heating a large number of zinc sprayed elementary tubes in one large heating device. There will be a difference in the amount of evaporation. In particular, when the amount of sprayed zinc is small, even if it is evaporated in the same amount as when it is large, the evaporation rate with respect to the remaining amount is large. Quality control becomes difficult. For this reason, when the maximum temperature reached in the preliminary diffusion heat treatment is relatively low, there is a problem that the variation in the evaporation rate becomes large and the quality control becomes difficult. For these reasons, when the flat surfaces of the zinc sprayed element tube are not overlapped, various problems occur regarding zinc evaporation.

  On the other hand, in the pre-diffusion heat treatment, when heating in a state in which the flat surfaces of the zinc sprayed element tube are overlapped, the amount of zinc evaporated in the pre-diffusion heat treatment is larger than in the case of not overlapping, Since the amount can be reduced, the above-mentioned problem relating to zinc evaporation can be prevented.

  In addition, when heated in an air atmosphere without overlapping the flat surfaces of the zinc sprayed element tube, the sprayed zinc will be oxidized. In order to suppress the oxidation of zinc, it is necessary to perform a heat treatment in an inert gas atmosphere such as nitrogen. However, in this case, it is necessary to prepare an inert gas, and a furnace for using the inert gas needs to be more airtight than a furnace heated in an air atmosphere, so the structure becomes complicated, Cost increases.

  On the other hand, when the pre-diffusion heat treatment is performed in a state where the flat surfaces of the zinc sprayed element tubes are overlapped with each other, since the sprayed zinc does not touch the air or is difficult to touch, the zinc is oxidized. It becomes difficult. Therefore, in the present invention, the preliminary diffusion heat treatment can be performed in an air atmosphere. In other words, in the present invention, by heating in a state in which the flat surfaces of the zinc sprayed element tube are overlapped with each other, even if heated in the air atmosphere, zinc is hardly oxidized, so that the preliminary diffusion heating is performed in the air atmosphere. Processing can be performed. Therefore, a furnace having a simple structure can be used, and the cost can be reduced.

In the preliminary diffusion heat treatment, the flat surfaces are overlapped so that the total diffusion amount ΣDt of zinc represented by the following formula (1) is in the range of 0.8 × 10 ^{−9 to} 4.6 × 10 ⁻⁹ m ^2. Heat the zinc sprayed element tube.
ΣDt = ΣD ₀ · exp (−Q / (R · Tn)) · Δtn (1)
(In the formula, Tn represents the total heating time from the time when the pre-diffusion heating is started and the temperature reaches 200 ° C. to the time when the pre-diffusion heating is finished and the temperature reaches 200 ° C. ) Is the temperature (° C.) of each minute time when divided by), D ₀ is 1.77 × 10 ⁻⁵ (m ² / s), Q is 117000 (kJ / mol), R Is 8.3145 (J / mol · K).)

Zinc sprayed on the surface of the flat tube made of aluminum alloy diffuses from the surface of the flat tube to the inside by heating. The diffusion coefficient D of zinc in aluminum is expressed by the following formula (3) according to the temperature at the time of heating based on the Arrhenius formula:
D = Do · exp (−Q / RT) (3)
Is required. Here, Do = 1.77 × 10 ⁻⁵ (m ² / s), Q = 117000 (kJ / mol), and R = 8.3145 (J / mol · K). The total diffusion amount ΣDt is obtained by multiplying the diffusion coefficient by time.

Regarding the diffusion amount in the actual heating heat pattern, the time and temperature are read from the heating temperature chart, the total heating time is divided into appropriate minute times Δtn, and each minute time is determined from each minute time tn and the temperature Tn at that time. ΔDtn of each is calculated and summed up to obtain a total diffusion amount. A more specific description will be given with reference to FIG. FIG. 9 is a schematic graph showing a heat pattern of heating. In FIG. 9, the temperature indicated by the dotted line is 200 ° C. (473 K). First, a minute time Δt 1, Δt 2,.・ Δt
n is divided into Δtf. Next, the temperatures T1, T2,... Tn,. Next, the time (seconds) and the temperature (K) of each minute time are substituted into the expression (3) to obtain the diffusion amount ΔDtn (m ² ) of each minute time. Next, they are summed, that is, ΣD ₀ · exp (−Q / (R · Tn)) · Δtn = ΣDt (m ² ) is obtained. When the temperature changes during each minute time, the temperature at the center of each minute time is set as the temperature of each minute time as shown in FIG.

  The minute time interval is preferably 1 minute or less. In Examples and Comparative Examples described later, the total diffusion amount was obtained by dividing the time interval of minute time by 30 seconds.

In order to obtain a good zinc diffusion state in the state of the heat exchanger core after being brazed, the total diffusion amount of zinc in the pre-diffusion heat treatment (ΣDt) and the total diffusion amount of zinc in the brazing heat treatment It is appropriate to set the sum of (ΣDt) to 2.0 × 10 ^{−9 to} 5 × 10 ⁻⁹ m ² . In recent years, ΣDt in brazing heat treatment of a general automobile heat exchanger is often about 0.4 × 10 ^{−9 to} 1.2 × 10 ⁻⁹ m ² , The ΣDt due to heating is suitably 0.8 × 10 ^{−9 to} 4.6 × 10 ⁻⁹ m ² .

For this reason, the total diffusion amount ΣDt in the preliminary diffusion heat treatment is 0.8 × 10 ^{−9 to} 4.6 × 10 ⁻⁹ m ² . If the total diffusion amount ΣDt in the pre-diffusion heat treatment is less than the above range, since the zinc diffusion amount is insufficient, the thickness as the sacrificial anode layer is reduced, the consumption time of the sacrificial anode layer is shortened, and the corrosion resistance is improved. Lower. Also, if the total diffusion amount ΣDt in the pre-diffusion heat treatment exceeds the above range, the zinc diffusion depth becomes deep and the thickness as the sacrificial anode layer becomes too thick, so that the sacrificial anode layer is consumed due to corrosion. The wall thickness of the flat tube remaining after the shrinkage is reduced, and the flat tube is liable to burst because it cannot withstand the pressure of the refrigerant.

  The aluminum alloy flat tube for heat exchanger of the present invention described below can be manufactured by the method for manufacturing the aluminum alloy flat tube for heat exchanger of the present invention.

The aluminum alloy flat tube for heat exchanger of the present invention is a flat tube formed of an aluminum alloy,
The aluminum alloy part contains 0.1 to 0.7% by mass of Cu and Zn, and is an aluminum alloy composed of the remaining aluminum and inevitable impurities,
Zinc is diffused from the outer edge of the aluminum alloy part to a position at a depth of 95 to 250 μm, and the zinc concentration on the surface of the flat surface of the aluminum alloy part is 1.5 to 15%, This is an aluminum alloy flat tube for a heat exchanger. The surface zinc concentration is a mass ratio (mass%) of zinc with respect to all metals in the outermost layer (surface), and is obtained, for example, in terms of mass ratio by surface element concentration analysis by EMPA.

  A zinc sprayed element tube used for manufacturing an aluminum alloy flat tube for a heat exchanger according to the present invention includes an aluminum alloy part having a flat tube shape and a zinc sprayed layer sprayed on the flat surface side of the aluminum alloy part. By subjecting this zinc sprayed element tube to pre-diffusion heat treatment, zinc in the zinc sprayed layer diffuses from the flat surface of the aluminum alloy part to the deep part of the aluminum alloy part, thereby forming a zinc diffusion layer. The zinc concentration distribution in the zinc diffusion layer is distributed so that the outer edge of the aluminum alloy portion, that is, the flat portion surface is high and decreases toward the deep portion. The zinc diffusion depth is the thickness of the zinc diffusion layer. In the present invention, the zinc diffusion layer is a portion having a zinc concentration of 0.2% by mass or more. For example, the zinc concentration distribution from the surface layer is measured by EPMA analysis of the cross section, and the zinc concentration is 0.2% by mass or more. Confirmed by finding the part.

  The aluminum alloy part is an aluminum alloy containing 0.1 to 0.7% by mass of Cu and Zn, and remaining aluminum and inevitable impurities.

  The Cu content in the aluminum alloy part is 0.1 to 0.7% by mass. Cu in the aluminum alloy increases the strength of the flat tube. If the content of Cu in the aluminum alloy part is less than the above range, the effect of improving the strength by Cu becomes insufficient, and even if the diffused zinc concentration is the same, the potential of the sacrificial anode layer becomes low. Therefore, the consumption rate of the sacrificial anode layer is increased. Moreover, when the said range is exceeded, the extrudability of a flat tube will fall.

  The aluminum alloy part can further contain one or two of 0.1 to 1.2% by mass of Si and 0.1 to 1.8% by mass of Mn.

  Si in the aluminum alloy increases the strength of the flat tube. The Si content in the aluminum alloy part is 0.1 to 1.2% by mass. If the content of Si in the aluminum alloy part is less than the above range, the effect of improving the strength by Si becomes insufficient, and if it exceeds the above range, the melting point of the flat tube is lowered and brazing is difficult. Become.

  Mn in the aluminum alloy increases the strength of the flat tube. The Mn content in the aluminum alloy part is 0.1 to 1.8% by mass. If the content of Mn in the aluminum alloy part is less than the above range, the effect of improving the strength by Mn becomes insufficient, and if it exceeds the above range, a coarse compound is produced and the extrudability of the flat tube is lowered.

  The aluminum alloy part further includes one or two of 0.01 to 0.3% by mass of Cr, 0.01 to 0.3% by mass of Zr, and 0.01 to 0.3% by mass of Ti. The above can be contained.

  Cr, Zr, and Ti in the aluminum alloy coarsen the crystal grain size after brazing and improve brazing properties. If the content of Cr, Zr, Ti in the aluminum alloy part is less than the above range, the effect of Cr, Zr, Ti will be insufficient, and if it exceeds the above range, a coarse compound is produced, so that the extrudability of the flat tube Decreases.

The zinc sprayed element tube used for the production of the aluminum alloy flat tube for heat exchanger of the present invention has 5-20 g / m ² , preferably 13-20 g / m ² , particularly preferably 15- It has a zinc sprayed layer in an amount of 20 g / m ² . Preliminary diffusion heat treatment is performed so that the total amount of zinc diffusion ΣDt is in the range of 0.8 × 10 ^{−9 to} 4.6 × 10 ⁻⁹ m ^{2 when} the amount of the zinc sprayed layer is in the above range, The total of the total diffusion amount of zinc in the pre-diffusion heat treatment and the total diffusion amount of zinc represented by the following formula (2) in the brazing heating of the heat exchanger core is 2 × 10 ^{−9 to} 5 × 10 ^{− In} a flat tube after brazing heating is performed at a temperature and time so as to be in the range of ⁹ m ² , the potential difference of the sacrificial anode layer in the surface layer portion with respect to the deep portion of the flat tube may be sufficiently reduced. Therefore, good corrosion resistance can be obtained. On the other hand, if the amount of the zinc sprayed layer is less than the above range, it is difficult to form a uniform zinc sprayed layer, and the surface layer of the flat tube after the pre-diffusion heat treatment and the brazing heating is performed. Since the zinc concentration in the part decreases, sufficient sacrificial anodic action cannot be obtained, and penetration corrosion tends to occur in the flat tube. When the above range is exceeded, the pre-diffusion heat treatment and the brazing heating are performed. In the later flat tube, since the zinc concentration in the surface layer portion of the flat tube is too high, the sacrificial anode layer is consumed quickly, and the strength of the flat tube is reduced. The amount of the zinc sprayed layer on the flat surface side of the aluminum alloy part is determined by fluorescent X-ray analysis.

Zinc diffuses on the flat surface side of the aluminum alloy portion of the aluminum alloy portion after the pre-diffusion heating. After pre-diffusion heating, zinc is diffused to a position of 95 to 250 μm, and the zinc concentration on the flat surface of the aluminum alloy part is 1.5 to 15%. Since the zinc diffusion depth and the surface zinc concentration are within the above ranges, the amount (thickness) of the sacrificial anode layer can be sufficiently secured after brazing even when the brazing heating time is short, and good corrosion resistance is obtained. be able to. On the other hand, when the diffusion depth of zinc is less than the above range, when the brazing heating time is short, the amount (thickness) of the sacrificial anode layer is insufficient and the zinc concentration on the surface becomes high, which is relatively reduced by corrosion. Since the sacrificial anode layer is consumed early, the corrosion resistance of the flat tube becomes insufficient. Further, if the zinc diffusion depth is less than the above range, the potential of the fillet at the joint with the fin becomes low, and the fin is easily peeled off. When the above range is exceeded, the amount (thickness) of the sacrificial anode layer becomes excessively thick, many sacrificial anode layers are consumed due to long-term corrosion, and the thickness of the remaining flat tube wall is reduced, Strength tends to decrease. On the other hand, if the zinc concentration on the surface is lower than the above, the potential difference of the sacrificial anode is insufficient and the corrosion resistance is lowered, and if higher than the above, the consumption rate of the sacrificial anode layer is increased and the corrosion resistance is lowered. The zinc diffusion depth is determined by preparing a sample in which the cross section of the test piece is filled with a resin and polishing it, and then analyzing the zinc concentration by EPMA or the like.

  The zinc diffusion depth will be described with reference to FIG. FIG. 10 is a schematic cross-sectional view in which a part of the aluminum alloy portion is cut out, (A) is a view before the preliminary diffusion heat treatment, and (B) is a view after the preliminary diffusion heat treatment. As shown in FIG. 10A, the zinc sprayed element tube 6 before the preliminary diffusion heat treatment has the zinc sprayed layer 5 on the flat surface 18 side of the aluminum alloy part 3. The position indicated by reference numeral 16 is the boundary between the aluminum alloy part 3 and the zinc sprayed layer 5, that is, the outer edge of the aluminum alloy part 3. Then, by subjecting the zinc sprayed element tube 6 to a pre-diffusion heat treatment, zinc in the zinc sprayed layer 5 diffuses from the flat surface 18 side of the aluminum alloy part 3 into the aluminum alloy part 3 and is shown in FIG. Thus, zinc diffuses to the position of the dotted line indicated by reference numeral 17 to form the zinc diffusion layer 15. The zinc concentration in the zinc diffusion layer 15 is distributed so that the outer edge (reference numeral 16) of the aluminum alloy portion 13, that is, the surface of the flat portion is high and decreases toward the deep portion. In the present invention, the zinc diffusion layer is a portion having a zinc concentration of 0.2% by mass or more. That is, the position of the dotted line indicated by the reference numeral 17 inside the aluminum alloy portion 13 indicates the position where the zinc concentration is 0.2 mass%. Therefore, portions of the aluminum alloy portion 13 from the reference numeral 16 to the reference numeral 17 are portions where zinc is diffused. And the distance from the position of the code | symbol 16 at this time to the position of the code | symbol 17 is the diffusion depth of zinc.

The method for producing a heat exchanger core of the present invention is obtained by an aluminum alloy flat tube for a heat exchanger by the method for producing an aluminum alloy flat tube for a heat exchanger of the present invention, and then the obtained aluminum alloy flat tube for a heat exchanger, A heat exchanger core in which an aluminum alloy brazing fin material clad with an Al—Si brazing material on both sides of an Al—Mn alloy is combined with a total diffusion amount of zinc in the pre-diffusion heat treatment, and the heat Heating at a temperature and time such that the total diffusion amount of zinc shown in the following formula (2) in brazing heating of the exchanger core is in the range of 2 × 10 ^{−9 to} 5 × 10 ⁻⁹ m ^2. It is the manufacturing method of the heat exchanger core characterized by performing brazing heat processing to perform.
ΣDt = ΣD ₀ · exp (−Q / (R · Tn)) · Δtn (2)
(In the formula, Tn represents the total heating time from the time when the brazing heating is started and the temperature reaches 200 ° C. until the temperature reaches 200 ° C. ) Is the temperature (° C.) of each minute time when divided by), D ₀ is 1.77 × 10 ⁻⁵ (m ² / s), Q is 117000 (kJ / mol), R Is 8.3145 (J / mol · K).)

For example, first, an aluminum alloy flat tube for a heat exchanger obtained by the method for producing an aluminum alloy flat tube for a heat exchanger according to the present invention, and an aluminum alloy in which an Al—Si brazing material is clad on both sides of an Al—Mn alloy. Laminated fins made of corrugated brazing fins are alternately laminated, and headers are combined at both ends of the flat tube, and a heat exchanger core is assembled. Next, the heat exchanger core is manufactured by applying the fluoride-based flux as a powder to the core of the heat exchanger and performing a brazing heat treatment in which it is heated and brazed in an inert gas atmosphere.

  Instead of aluminum alloy brazing fins clad with Al-Si brazing filler metal on both sides of the Al-Mn alloy, Al-Mn alloy bare fins and corrugated fins are laminated alternately, It is also possible to manufacture a heat exchanger core by placing a wax at the portion where the tube and the fin are in contact and performing a brazing heat treatment in the same manner. The brazing method is a method of placing an Al-Si alloy brazing material wire near the junction between the flat tube and the fin, a method of sandwiching an Al-Si alloy brazing material foil between the flat tube and the fin, Al-Si alloy powder or There is a method of coating Si powder near the junction between the flat tube and the fin.

  Thus, the aluminum alloy flat tube for heat exchangers of the present invention is also used for manufacturing a heat exchanger core using any one of brazing fins and bare fins.

And in the manufacturing method of the heat exchanger core of this invention of this invention, in brazing heat processing, it shows to the total diffusion amount of zinc in pre-diffusion heat processing, and Formula (2) in brazing heating of a heat exchanger core Heating is performed at a temperature and time such that the total amount of zinc diffused is in the range of 2 × 10 ^{−9 to} 5 × 10 ⁻⁹ m ² . The method for calculating the total amount of zinc diffusion is the same as the method for calculating the total amount of zinc diffusion in the preliminary diffusion heat treatment.

  If the total diffusion amount of zinc in the pre-diffusion heat treatment and the total diffusion amount of zinc in the brazing heating is less than the above range, the zinc diffusion amount is insufficient, so the sacrificial anode layer is thin. Thus, the consumption time of the sacrificial anode layer is shortened and the corrosion resistance is lowered. Further, if the total diffusion amount of zinc in the pre-diffusion heat treatment and the total diffusion amount of zinc in the brazing heating exceeds the above range, the zinc diffusion depth becomes deep and the thickness as the sacrificial anode layer becomes thick. Therefore, the thickness of the core material remaining after the sacrificial anode layer is consumed due to corrosion is reduced, and the flat tube is liable to burst because it cannot withstand the pressure of the refrigerant.

  The heating temperature in the brazing heat treatment is such that the total of the total diffusion amount of zinc in the pre-diffusion heat treatment and the total diffusion amount of zinc shown in Formula (2) in the brazing heating of the heat exchanger core is within the above range. The maximum temperature is preferably 580 to 625 ° C., particularly preferably 590 to 615 ° C.

  The heating time in the brazing heat treatment is such that the total of the total amount of zinc diffused in the pre-diffusion heat treatment and the total amount of zinc diffused in formula (2) in the brazing heating of the heat exchanger core is within the above range. It is suitably selected depending on the relationship with the heating time so that it is preferably 300 to 1800 seconds, particularly preferably 300 to 1200 seconds.

  And by performing brazing heat processing, the diffusion depth of zinc will be 140-260 micrometers, and the zinc concentration of the surface of the flat surface of an aluminum alloy part will be 1.0-8%.

  The heat exchanger core of the present invention is a heat exchanger core obtained by performing the method for producing a heat exchanger core of the present invention.

(Examples and Comparative Examples)
A billet of aluminum alloy with a diameter of 80 mm having a composition shown in Tables 1 and 3 was produced by continuous casting, and the obtained billet was homogenized by holding at 600 ° C. for 6 hours.
Next, this billet was heated at 550 ° C. and hot-extruded to produce an extruded flat tube 211 having a cross-sectional shape of 0.4 mm thick as shown in FIG. Immediately after the extrusion, a predetermined amount of pure zinc was sprayed on the flat portion of the flat tube, and aligned and wound in a coil shape. Then, while unwinding the coil, the tube axis was made into a straight straight tube, cut into a predetermined dimension, and then bundled in a state of being aligned so that the flat surfaces overlap each other.
This bundled straight zinc-sprayed extruded flat tube or a coiled zinc-sprayed extruded flat tube that has been coiled in a coiled shape was heated in an air atmosphere to perform a pre-diffusion heat treatment of zinc. . The actual temperature at this time was measured, and ΣDt was calculated.
Subsequently, the zinc spray-extruded flat tube after the pre-diffusion heating treatment was brazed for 5 to 20 minutes at a maximum temperature of 600 ° C. alone in a nitrogen gas atmosphere. The body temperature was also measured during brazing heating, and ΣDt was calculated in the same manner.
The obtained single pipe after brazing was subjected to a CASS test for 1500 hours, and the corrosion resistance was evaluated by whether or not through corrosion occurred. The CASS test results are shown in Table 2, Table 3, Table 5, and Table 6.

1) Straight pipe alignment: A form in which a number of flat surfaces of a straight pipe are stacked and laminated. Coil alignment: A form in which coils are aligned and wound after spraying pure zinc 2) Zn diffusion depth: By EPMA analysis of a cross section The Zn concentration distribution from the surface layer is measured, and the depth at which the Zn concentration is 0.2 mass% is defined as the diffusion depth.
3) Zn concentration on flat surface: The mass concentration of Zn on the surface layer was measured by EPMA analysis on the surface. 4) Residual ratio of zinc: (total amount of diffused Zn / amount of Zn deposited by zinc spraying) × 100 (%). Diffusion Zn was calculated from the Zn concentration distribution in the cross section.

1) Straight pipe alignment: Form in which flat surfaces of straight pipes are overlapped and stacked in large numbers Straight pipe alone: Form in which straight pipes are separated one by one without overlapping flat faces 2) Zn diffusion depth : By the EPMA analysis of the cross section, the Zn concentration distribution from the surface layer is measured, and the depth at which the Zn concentration is 0.2 mass% is defined as the diffusion depth.
3) Zn concentration on flat surface: The mass concentration of Zn on the surface layer was measured by EPMA analysis on the surface. 4) Residual ratio of zinc: (total amount of diffused Zn / amount of Zn deposited by zinc spraying) × 100 (%). Diffusion Zn was calculated from the Zn concentration distribution in the cross section.

Claims (9)

A zinc sprayed element tube in which a zinc sprayed layer of 5 to ²⁰ g / m ² is provided on a flat surface of an aluminum alloy flat tube containing 0.1 to 0.7% by mass of Cu and the balance aluminum and inevitable impurities. Are overlapped with each other, the maximum temperature reached is 430 to 550 ° C., and the total diffusion amount ΣDt of zinc represented by the following formula (1) is 0.8 × 10 ^{−9 to} 4.6 × 10 ⁻⁹ (m ² A method for producing an aluminum alloy flat tube for a heat exchanger, wherein a pre-diffusion heat treatment is performed so as to be in a range of
ΣDt = ΣD ₀ · exp (−Q / (R · Tn)) · Δtn (1)
(In the formula, Tn represents the total heating time from the time when the pre-diffusion heating is started and the temperature reaches 200 ° C. to the time when the pre-diffusion heating is finished and the temperature reaches 200 ° C. ) Is the temperature (K) of each minute time when divided by), D ₀ is 1.77 × 10 ⁻⁵ (m ² / s), Q is 117000 (kJ / mol), R Is 8.3145 (J / mol · K).)   The method for producing an aluminum alloy flat tube for a heat exchanger according to claim 1, wherein the pre-diffusion heat treatment is performed in an air atmosphere.   The aluminum alloy further contains one or two of 0.1 to 1.2% by mass of Si and 0.1 to 1.8% by mass of Mn. The manufacturing method of the aluminum alloy flat tube for heat exchangers of any one of 2.   The aluminum alloy further includes one or two of 0.01 to 0.3% by mass of Cr, 0.01 to 0.3% by mass of Zr, and 0.01 to 0.3% by mass of Ti. It contains the above, The manufacturing method of the aluminum alloy flat tube for heat exchangers of any one of Claims 1-3 characterized by the above-mentioned. A flat tube formed of an aluminum alloy;
The aluminum alloy part contains 0.1 to 0.7% by mass of Cu and Zn, and is an aluminum alloy composed of the remaining aluminum and inevitable impurities,
Zinc is diffused from the outer edge of the aluminum alloy part to a position at a depth of 95 to 250 μm, and the zinc concentration on the surface of the flat surface of the aluminum alloy part is 1.5 to 15%, Aluminum alloy flat tube for heat exchanger.   6. The aluminum alloy part further contains one or two of 0.1 to 1.2% by mass of Si and 0.1 to 1.8% by mass of Mn. The aluminum alloy flat tube for heat exchangers as described.   The aluminum alloy portion may further include one or two of 0.01 to 0.3% by mass of Cr, 0.01 to 0.3% by mass of Zr, and 0.01 to 0.3% by mass of Ti. The aluminum alloy flat tube for a heat exchanger according to any one of claims 5 and 6, wherein the flat tube contains a seed or more. An aluminum alloy flat tube for a heat exchanger is obtained by the method for producing an aluminum alloy flat tube for a heat exchanger according to any one of claims 1 to 4, and then the obtained aluminum alloy flat tube for a heat exchanger and an Al-Mn system A heat exchanger core in which an aluminum alloy brazing fin material clad with an Al-Si brazing material is clad on both surfaces of the alloy, a total diffusion amount of zinc in the pre-diffusion heating treatment, and a heat exchanger core Brazing heating in which the total diffusion amount of zinc shown in the following formula (2) in brazing heating is heated at a temperature and time such that the total is in the range of 2 × 10 ^{−9 to} 5 × 10 ⁻⁹ m ^2. The manufacturing method of the heat exchanger core characterized by performing a process.
ΣDt = ΣD ₀ · exp (−Q / (R · Tn)) · Δtn (2)
(In the formula, Tn represents the total heating time from the time when the brazing heating is started and the temperature reaches 200 ° C. until the temperature reaches 200 ° C. ) Is the temperature (° C.) of each minute time when divided by), D ₀ is 1.77 × 10 ⁻⁵ (m ² / s), Q is 117000 (kJ / mol), R Is 8.3145 (J / mol · K).)   The heat exchanger core obtained by performing the manufacturing method of the heat exchanger core of Claim 8.