System for grooving and rolling linear member and flat heat exchanger tube resulting therefrom

Abstract

 A system for grooving and rolling a linear member (11) comprises a first roll (1) having a groove forming part (1A) provided with a plurality of protrusions (2) and edge rolling parts (1B) disposed on both sides thereof, a second roll (8) disposed opposite to the first roll, and flanges (9) mounted to the first or second roll for restraining extension of the linear member in the cross direction thereof. The groove forming part is symmetrically constructed in the cross direction of the linear member, and has at least one buffer area (3) disposed continuously in the longitudinal direction thereof.

Description

BACKGROUND OF THE INVENTION

[0001] The present invention relates generally to a system for grooving and rolling a linear member, and more particularly to, same used in a pre-welding process upon manufacture of a heat exchanger tube with grooved inner surface for a heat exchanger for an air conditioner, and a flat heat exchanger tube resulting therefrom.

[0002] An air conditioner for domestic use has been reduced in size to make a living space comfortable. A reduction in size of the air conditioner is obtained by decreasing the entirety of component parts.

[0003] The air conditioner has a heat exchanger part which occupies a large part therein, and includes a heat exchanger tube through which heating medium passes, the heat exchanger tube being made of copper with excellent heat conductivity, and having an inner surface with grooves formed, for example, in a spiral, so as to largely improve the efficiency.

[0004] As to a common method of manufacturing the heat exchanger tube with grooved inner surface, a billet is subjected to extrusion, rolling, and drawing in turn, then grooved, obtaining a seamless copper tube.

[0005] In recent years, for obtaining a small diameter heat exchanger tube with grooved inner surface, a method as shown in Fig. 7 becomes often adopted in which an original linear member 10 is subjected to grooving/rolling by a grooved rolling part 21, and shaped into a tube by a tube forming part 22, a butt portion thereof being welded by a seam welding equipment 23 to obtain a welded heat exchanger tube 13.

[0006] The method on high frequency welding enables a reduction in diameter of the copper tube as compared with the seamless method, resulting in an advantage in connection with countermeasures against a reduction in size of the heat exchanger part.

[0007] On the other hand, an air conditioner for use in a motor vehicle includes a heat exchanger having harmonica tubes 25 obtained by extrusion molding of aluminum as shown in Fig. 8A, or inner fin tubes 26 each obtained by inserting a wavy fin or rib 28 into an aluminum flat tube 27 subjected to high frequency welding which are soldered as shown in Fig. 8B, and outer fins 29 superimposed alternately as shown in Fig. 8C. This air conditioner is used in ventilating a portion of the outer fins 29.

[0008] As compared with the seamless heat exchanger tube, that one produced by high frequency welding has a welded portion which needs ensured reliability.

[0009] For obtaining sure welding, conditions necessary to welding should be satisfied. For this purpose, some conditions necessary to welding but, actually, with possible deviation from a proper value should be eliminated.

[0010] The principal conditions of welding are as follows: 1) welding temperature which depends on heat input, speed, thickness, approach angle, and resistance; 2) butt which depends on parallel butt and pressure welding width which in turn depends on width, thickness, preforming, and slit shape; 3) atmosphere which depends on non-oxidation which in turn depends on Argon (Ar) gas flow.

[0011] Control for input heat of 1) is carried out in using various fluctuation factors, and control methods for the welding temperature of 1) and the welding atmosphere of 3) are established.

[0012] As to a control method for butt, control should be carried out in processes of rolling of the linear member, and shaping and roll forming of slits or grooves, however, control on detected fluctuation factors cannot currently be adopted. Up to the present, it is carried out in accordance with inspection of a size of the linear member and a section of the slit to select nondefectives which may have a practical tolerance of accuracy or dispersion.

[0013] The most important factors are conditioning of an edge of an edge portion of the linear member, width thereof, and circular forming of the edge portion. Ordinarily, this is ensured by improvement in accuracy of slit cutting and design of a roll groove shape for roll forming. Thus, a method is adopted that after carrying out grooving/rolling of the linear member out of a line, slit cutting is carried out on the entirety of the width thereof on the line. On the other hand, a groove shaping method for the linear member is proposed which carries out circular forming of the edge portion (see, for example, JP-A 4-157017). However, this method is still unsatisfying due to dispersion of a width and end face shape of the linear member.

[0014] Therefore, when carrying out roll forming and welding, the linear member grooved according to the actual groove shaping method has welds unstable and insufficient in strength, resulting in impossible elimination of secular dispersion.

[0015] On the other hand, preparation is made actually for using, as a heat exchanger cooling medium, substitute freon which decomposes before reaching the ozone layer in place of freon which destroys same.

[0016] However, since substitute freon has about 20 % reduced heat exchanger characteristic, countermeasures should be taken in view of total abolition of the use of freon.

[0017] Moreover, with substitute freon, a heat exchanger area of the heat exchanger tube should be increased by a reduced part of heat exchanger characteristic, which produces a problem of a weight and size thereof. Therefore, performance of the heat exchanger tube should be improved to fully compensate a reduction in heat exchanger characteristic.

[0018] It is, therefore, an object of the present invention to provide a system for grooving and rolling a linear member without any dispersion of a width and end face shape thereof and with sufficient heat exchanger characteristic, and a flat heat exchanger tube resulting therefrom.

SUMMARY OF THE INVENTION

[0019] According to an aspect of the present invention, there is provided a system for grooving and rolling a linear member, comprising:
   a first roll, said first roll having a groove forming part provided with a plurality of protrusions and edge rolling parts disposed on both sides of said groove forming part, said groove forming part being symmetrically constructed in the cross direction of the linear member, said groove forming part having at least one buffer area disposed continuously in the longitudinal direction of the linear member;
   a second roll disposed opposite to said first roll; and
   a means for restraining an extension of the linear member in the cross direction thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

[0020] 

Fig. 1A is a sectional views showing groove forming according to a first preferred embodiment of the present invention;

Figs. 1B and 1C are views similar to Fig. 1A, each showing edge rolling according to the first preferred embodiment;

Fig. 2A is a view similar to Fig. 1C, showing an original linear member according to the first preferred embodiment;

Fig. 2B is a view similar to Fig. 2A, showing a linear member grooved and rolled according to the first preferred embodiment;

Fig. 3A is a view similar to Fig. 2B, showing groove forming according to a second preferred embodiment of the present invention;

Figs. 3B and 3C are views similar to Fig. 3A, each showing edge rolling according to the first preferred embodiment;

Fig. 4A is a view similar to Fig. 3C, showing an original linear member according to the second preferred embodiment;

Fig. 4B is a view similar to Fig. 4A, showing a linear member grooved and rolled according to the second preferred embodiment;

Fig. 5A is an enlarged fragmentary section showing a flat heat exchanger tube according to the second preferred embodiment;

Fig. 5B is an enlarged view of a portion "a" in Fig. 5A;

Fig. 6A is a perspective view showing a flat tube and a wavy fin to be inserted therein;

Fig. 6B is a view similar to Fig. 6A, showing the flat tube with the wavy fin inserted;

Fig. 7 is a schematic view showing a method of manufacturing a heat exchanger tube with grooved inner surface;

Figs. 8A and 8B are view similar to Fig. 6B, each showing a known heat exchanger tube for an automotive air conditioner; and

Fig. 8C is a fragmentary side view showing a known heat exchanger.

DETAILED DESCRIPTION OF THE INVENTION

[0021] Referring to the drawings wherein like reference numerals designate like parts throughout the views, preferred embodiments of the present invention will be described.

[0022] Referring to Figs. 1A to 2B, there is shown a first preferred embodiment wherein reference numerals 1 and 8 designate a groove forming roll and a support roll, respectively, in a system for grooving and rolling a linear member. 10 designates an original linear member, and 11 designates a linear member rolled and grooved.

[0023] Referring particularly to Fig. 1A, the groove forming roll 1 comprises a groove forming part 1A, and edge rolling parts 1B disposed on both ends thereof. The groove forming part 1A is provided with a plurality of grooving protrusions 2 with a pitch p, a height h₂ and an inclination angle ϑ, and a section formed substantially in a trapezoid, and a lower protrusion 3 located in the center of the groove forming part 1A for contacting a surface of the original linear member upon grooving/rolling.

[0024] Referring to Fig. 1B, each edge rolling part 1B comprises a small diameter portion 7 connected to a base portion of the grooving protrusion 2' disposed at an end of the groove forming part 1A, and an end rolling part 5 having a bevel portion. A width w₂ of the small diameter portion 7 is larger than a width w₁ of a groove portion 4 of the groove forming part 1A.

[0025] The support roll 8 is provided with flanges 9 at both ends thereof for arresting elongation of the linear member in the cross direction thereof upon grooving/rolling. A height of the flange 9 is determined so that when the flange 9 comes in contact with the end rolling part 5 of the groove forming roll 1, a distance between the grooving protrusion 2' of the groove forming part 1A and a surface of the support roll 8 is equal to a predetermined thickness t_min of each groove 12 of the linear member 11 grooved and rolled.

[0026] Referring to Fig. 1C, the width w₂ of the small diameter portion 7' connected to the base portion of the grooving protrusion 2' of the edge rolling part 1B is not equal to the width w₁ of the groove portion 4 of the groove forming part 1A, while a diameter of the small diameter portion 7' is smaller than a diameter of the groove portion 4.

[0027] The groove forming roll 1 and the support roll 8 are disposed so that the flanges 9 of the support roll 8 contact the end rolling part 5 of the groove forming roll 1 constructed as described above, which are rotated so that the original linear member 10 as shown in Fig. 2A passes therebetween for grooving/rolling.

[0028] When the original linear member 10 comes between the rolls 1 and 8, each grooving protrusion 2 of the groove forming part 1A presses the surface of the original linear member 10 to obtain the thickness t_min, thus forming the groove 12.

[0029] Referring to Fig. 1A, a portion of the linear member extruded from the groove 12 by the grooving protrusion 2 serves to come in the groove portion 4 of the groove forming roll 1 in increasing a thickness of an adjacent portion thereof, forming a protrusion portion with a thickness t_max. A portion of the linear member which could not come in the groove portion 4 due to a greater thickness t₀ of the linear member than a reference value, etc. moves in the cross direction of the linear member so as to come in a clearance g₁ which is formed on both sides of the lower protrusion 3 disposed in the center of the groove forming roll 1.

[0030] That is, as best seen in Fig. 2B, the clearance g₁ serves as a buffer area C₁ for alleviating elongation of the linear member 11 in the cross direction thereof.

[0031] Referring to Fig. 1B, simultaneously with grooving, both ends of the linear member 11 are rolled by the end rolling part 1B. However, since elongation of the linear member 11 in the cross direction thereof by rolling is arrested by the flanges 9 of the support roll 8, a portion of the linear member extruded in the same way as described above with a greater volume than a reference value comes in a clearance g₂ formed in the small diameter portion 7.

[0032] That is, as best seen in Fig. 2B, the clearance g₂ also serves as a buffer area C₂ for alleviating elongation of the linear member 11 in the cross direction thereof.

[0033] According to this embodiment, since elongation of the linear member in the cross direction thereof produced upon grooving/rolling can be not only restricted by the support roll 8, but absorbed by the buffer areas C₁, C₂, the linear member 11 grooved and rolled presents no dispersion of a width and end face shape even if the original linear member 10 has some dispersion of a thickness, width, etc. It is to be noted that in Figs. 1A to 2B, reference numeral A designates a groove portion of the linear member 11, and B designates an edge portion thereof.

[0034] When the groove forming roll 1 is used which has the grooving protrusion 2 with the pitch p of 0.55 mm on average, the height

of 0.16 mm, and the inclination angle ϑ of about 10° , and the original linear member 10 made of phosphor deoxidized copper and with the thickness of 0.3 mm and the width of 20.8 mm is subjected to grooving/rolling out of a line, the linear member 11 is obtained which has a groove pitch of 0.55 mm on average, a thickness t_max of 0.38 mm and t_min of 0.22 mm, and a groove angle 10°.

[0035] This linear member 11 grooved and rolled is subjected to roll forming on the entirety of the outer periphery thereof so as to obtain a finished tube with a diameter of 6.35 mm. Then, a butt portion of the linear member 11 is subjected to high frequency welding by a seam welding equipment.

[0036] In this case, since grooving/rolling ensures forming of the grooves 12 with a width regulated accurately at a certain value, welding can be carried out with less butt dispersion based on roll forming on the entirety of the outer periphery of the linear member 11, i.e., a butt angle of ± 2° (+ 20°, - 0° in the prior art) and a height dispersion of ± 0.1 mm (± 0.25 mm in the prior art).

[0037] Thus, not only welding is largely improved in strength, but in quality for a long period of time, i.e., one defect per 50 Km (one defect per 10 Km in the prior art), resulting in largely increased and stabilized reliability of welding quality. Moreover, a yield is improved from prior art 80 % to 95 %.

[0038] Since the system is less adjusted with material variations, an operation rate thereof is increased from prior art 70 % to 95 %.

[0039] Moreover, due to less butt angle and height dispersion, a life of consumables is considerably improved, e.g., for a seam guide, 100 hours → 400 hours, and for a squeeze roll, 400 hours → 800 hours.

[0040] According to this embodiment, the linear member 11 has the buffer area C₁ disposed in the center thereof as shown in Fig. 1A, and the buffer area C₂ disposed on the side end thereof as shown in Figs. 1B and 1C. Alternatively, the linear member 11 may has either of the buffer areas C₁, C₂.

[0041] Moreover, according to this embodiment, the grooving protrusion 2 of the groove forming roll 1 is shaped in a trapezoid for obtaining a trapezoidal groove, however, it may be freely selected. For this grooving/rolling, it is important to satisfy the following conditions:

a) The grooves 12 of the linear member are symmetrically formed,

b) The groove forming roll 1 has in the cross direction thereof at least one buffer area which continues in the longitudinal direction of the linear member,

c) The groove forming roll 1 or the support roll 8 has on both ends thereof flange portions for arresting extension of the linear member in the cross direction thereof, and

d) A thickness t_e of the end portion of the linear member is:

.

[0042] Referring next to Figs. 3A to 4B, there is shown a second preferred embodiment of the present invention.

[0043] Referring particularly to Fig. 3A, reference numeral 1' designates a groove forming roll for a linear member for an inner fin type welded flat heat exchanger tube, and 4' designates a shallow and flat groove portion located at a predetermined pitch position in a groove portion 4 of a groove forming roll 1'.

[0044] Referring to Figs. 4A and 4B, 10' designates an original aluminum linear member, 11' designates an aluminum linear member formed by the groove forming roll 1', and 16 designates a soldering protrusion formed by the groove portion 4' of the groove forming roll 1'.

[0045] The other constitution is substantially the same as the first preferred embodiment except that the groove forming roll 1' and a width thereof are slightly different from that ones as shown in Figs. 1A to 1C.

[0046] In the same manner as the first preferred embodiment, the original linear member 10' is grooved and rolled by the groove forming roll 1' to obtain the linear member 11'. The linear member 11' is subjected to roll forming on the entirety of the outer periphery thereof so as to form a flat tube. Then, a butt portion of the linear member 11' is subjected to high frequency welding by the seam welding equipment, obtaining a flat tube with grooved inner surface.

[0047] Referring to Figs. 5A to 6B, this flat tube with grooved inner surface 15 is cut to a predetermined length (between about 150 mm and 500 mm) so as to fit a length of an automotive air conditioner. A solder 18 is placed on inner and outer surfaces of the flat tube 15 as best seen in Fig. 5B, and a wavy fin 17 with the solder 18 placed and substantially the same length as the flat tube 15 is inserted therein so that each convex portion thereof contacts the corresponding soldering protrusion 16 as best seen in Figs. 5A and 6A.

[0048] The flat tube 15 having the wavy fin 17 inserted is heated in a furnace so that the convex portion of the wavy fin 17 is soldered to the corresponding soldering protrusion 16 on the inner surface of the flat tube 15, obtaining an inner fin type flat heat exchanger tube with grooved inner surface 14 as shown in Fig. 6B.

[0049] When the groove forming roll 1 is used which has the grooving protrusion 2 with the pitch p of 0.55 mm on average, the height

of 0.16 mm, and the inclination angle ϑ of about 10°, and the original linear member 10' made of three-layer clad aluminum and with the thickness of 0.3 mm and the width of 42.2 mm is subjected to grooving/rolling out of a line, the linear member 11' is obtained which has the groove pitch of 0.55 mm on average, the thickness t_max of 0.38 mm and t_min of 0.22 mm, and the groove angle 10°.

[0050] This linear member 11 grooved and rolled is subjected to roll forming on the entirety of the outer periphery thereof, which is formed in a flat shape so as to obtain a finished flat tube with long diameter of 20 mm x small diameter of 2 mm. Then, a butt portion of the linear member 11' is subjected to high frequency welding by the seam welding equipment.

[0051] In this case, since grooving/rolling ensures forming of the grooves 12 with a width regulated accurately at a certain value, welding can be carried out with less butt dispersion based on roll forming on the entirety of the outer periphery of the linear member 11', i.e., the butt angle of ± 2° (+ 20°, - 0° in the prior art) and the height dispersion of ± 0.1 mm (± 0.25 mm in the prior art).

[0052] Thus, not only welding is largely improved in strength, but in quality for a long period of time, i.e., one defect per 50 Km (one defect per 10 Km in the prior art), resulting in largely increased and stabilized reliability of welding quality. Moreover, a yield is improved from prior art 83 % to 98 %.

[0053] Since the system is less adjusted with material variations, an operation rate thereof is increased from prior art 72 % to 97 %.

[0054] Moreover, due to less butt angle and height dispersion, a life of consumables is considerably improved, e.g., for a seam guide, 350 hours → 920 hours, and for a squeeze roll, 800 hours → 3000 hours.

[0055] According to this embodiment, the linear member 11' has the buffer area C₁ disposed in the center thereof as shown in Fig. 3A, and the buffer area C₂ disposed on the side end thereof as shown in Figs. 3B and 3C. Alternatively, the linear member 11' may has either of the buffer areas C₁, C₂.

[0056] Moreover, according to this embodiment, the grooving protrusion 2 of the groove forming roll 1' is shaped in a trapezoid for obtaining a trapezoidal groove, however, it may be freely selected. For this grooving/rolling, it is important to satisfy the following conditions:

a) The grooves 12 of the linear member are symmetrically formed, except ones to be soldered to the fin 17,

b) The groove forming roll 1' has in the cross direction thereof at least one buffer area which continues in the longitudinal direction of the linear member, and

c) The groove forming roll 1' or the support roll 8 has on both ends thereof flange portions for arresting extension of the linear member in the cross direction thereof.

[0057] Having described the present invention in connection with the preferred embodiments, it is to be noted that the present invention is not limited thereto, and various changes and modifications are possible without departing from the spirit of the present invention.

Claims

1. A system for grooving and rolling a linear member, comprising:
   a first roll, said first roll having a groove forming part provided with a plurality of protrusions and edge rolling parts disposed on both sides of said groove forming part, said groove forming part being symmetrically constructed in the cross direction of the linear member, said groove forming part having at least one buffer area disposed continuously in the longitudinal direction of the linear member;
   a second roll disposed opposite to said first roll; and
   a means for restraining an extension of the linear member in the cross direction thereof.

2. A system as claimed in claim 1, wherein said at least one buffer area of said groove forming part is located in a center portion thereof wherein one of said plurality of protrusion of said first roll is disposed to contact a surface of the linear member.

3. A system as claimed in claim 2, wherein said at least one buffer area of said groove forming part is located between one of said edge rolling parts and adjacent one of said plurality of protrusions of said first roll.

4. A system as claimed in claim 1, wherein said restraining means is in the form of a flange mounted to said first roll.

5. A system as claimed in claim 4, wherein said restraining means is in the form of a flange mounted to said second roll.

6. A system as claimed in claim 1, wherein ones of said plurality of protrusions of said groove forming part are disposed in a predetermined pitch position to contact a surface of the linear member, each of said ones of said plurality of protrusions serving to form a portion to be soldered to an inner fin.

Drawing