The present invention relates to a heat exchanger.
Japanese Patent Application Publication No. 2011-7411 discloses a heat exchanger including a plurality of stacked core plates, oil flow passages each formed between adjacent two of the core plates, and coolant flow passages each formed between adjacent two of the core plates. The oil flow passages and the coolant flow passages are alternatingly formed.
In the heat exchanger of the above-described patent document, a fin plate is disposed in an oil flow passage. Each of the core plates constituting a coolant flow passage includes a plurality of protruding portions protruding toward the coolant flow passage. The fin plates and the protruding portions are provided for improving the heat exchanging efficiency between the oil and the coolant.
However, in the heat exchanger of the above-described patent document, the oil flows from one of a pair of oil holes provided on a diagonal line of the core plate, to the other of the pair of the oil holes. Moreover, the oil flows from one of a pair of coolant holes provided on a diagonal line of the core plate, to the other of the pair of the coolant holes.
Accordingly, the oil is easy to flow along the diagonal line of the core plate in which the oil holes are formed, the diagonal line becoming a shortest distance.
That is, the flow of the fluid flowing between the core plates becomes nonuniform flow as a whole. There are room for improvement of the heat exchange efficiency.
According to one aspect of the present invention, A heat exchanger comprises: a plurality of rectangular core plates stacked; a plurality of plate oil flow passages and a plurality of plate coolant flow passages alternatingly formed between the plurality of the core plates; a plurality of rectangular fin plates each disposed at least to one flow passage of the plurality of the plate oil flow passages and the plate coolant flow passages; the core plates each including a pair of oil holes and a pair of coolant holes; in a case where a first reference line and a second reference line are defined as lines which pass through a center of the fin plate, and which are perpendicular to each other in a plane of each of the core plates, each of the fin plates having an anisotropy in which a passage resistance in a direction parallel to the first reference line is smaller than a passage resistance parallel to the second reference line, the pair of the oil holes being positioned on an outer edge of one of the core plates, the pair of the oil holes being positioned at symmetrical positions with respect to the center of the one of the core plates to sandwich the center of the one of the core plates, and the pair of the oil holes being positioned to sandwich one of the fin plates along the first reference line, and the pair of the coolant holes being positioned on the outer edge of the one of the core plates, the pair of the coolant holes being positioned at symmetrical positions with respect to the center of the one of the core plates to sandwich the center of the one of the core plates, and the pair of the coolant holes being positioned to sandwich the one of the fin plates along the first reference line, wherein the pair of the oil holes are positioned on a diagonal line of one of the core plates; and the pair of the coolant holes are positioned on a diagonal line of the one of the core plates which is not different from the diagonal line on which the pair of the oil holes are formed.
Hereinafter, embodiments of the present invention are explained in detail with reference to the drawings. Besides, in below-described explanations, terms such as “upward”, “downward”, “a top portion”, and “a bottom portion” are used with reference to a posture of
First, a summary of an oil cooler 1 which is a heat exchanger according a first embodiment of the present invention is explained with reference to
As shown in
The heat exchanger section 2 includes first core plates 5 which are a plurality (many) of core plates; and second core plates 6 which are a plurality (many) of core plates. The first core plates 5 and the second core plates 6 have an identical basic structure. The first core plates 5 and the second core plates 6 are alternatively stacked each other, so that plate oil flow passages 7 (cf.
In this embodiment, as shown in
The plurality of first and second core plates 5 and 6, the top plate 3, the bottom plate 4, the plurality of the first fin plates 9, and the plurality of the second fin plates 10 are integrally jointed with each other by brazing. Specifically, these plates 3, 5, and 6 are formed by using clad metals formed by covering surfaces of base material of the aluminum alloy with soldering layer. The above-described plates are temporarily assembled at predetermined positions. Then, this is heated within a furnace, so that the plates are jointed by the brazing.
The first core plates 5 which are positioned at an uppermost portion and a lowermost portion of the heat exchanger section 2 have structures slightly different from structures of the normal first core plate 5 which are positioned at intermediate portions of the heat exchanger section 2, for relationship with the top plate 3 and the bottom plate 4.
For example, in this embodiment, the first core plate positioned at the lowermost portion of the heat exchanger 2 is thicker than the other first core plates 5.
Each of the first core plates 5 and the second core pleats 6 is formed by press-forming a thin base metal of the aluminum alloy. Each of the first core plates 5 and the second core pleats 6 is formed into a rectangular overall shape (substantially square). Each of the first core plates 5 and the second core plates 6 includes a pair of oil through holes 11 and 11 which are a pair of oil holes, and a pair of coolant through holes 12 and 12 which are a pair of coolant holes.
Moreover, in this embodiment, each of the first core plates 5 and the second core plates 6 includes a pair of through holes 13 and 13 through which the oil and the coolant do not pass, as shown in
The top plate 3 includes a coolant introduction portion 14 connected to one of the coolant through holes 12 of the uppermost portion of the heat exchanger section 2; and a coolant discharge portion 15 connected to the other of the coolant through holes 12 of the uppermost portion of the heat exchanger section 2. As shown in
As shown in
The pair of the oil through holes 11 and 11 are positioned at an outer edge of each of the core plates. The pair of the oil through holes 11 and 11 are formed at positions symmetrical with each other with respect to a center of each of the core plates (to sandwich the center of each of the core plates). Specifically, as shown in
The pair of the coolant through holes 12 and 12 are positioned at an outer edge of each of the core plates. The pair of the coolant through holes 12 and 12 are formed at positions symmetrical with each other with respect to a center of each of the core plates (to sandwich the center of each of the core plates). Specifically, as shown in
Besides, the coolant through holes 12 are formed so as not to be overlapped with the oil through holes 11. Specifically, the coolant through holes 12 are formed on the diagonal line of the core plate which is different from the diagonal line of the core plate of the oil through holes 11.
As shown in
The coolant introduced from the coolant introduction portion 14 of the top plate 3 flows through the plate coolant flow passages 8. As a whole, the coolant flows within the heat exchanger section 2 in a direction perpendicular to a stacking direction of the core plates. Then, the coolant reaches the coolant discharge portion 15 of the top plate 3. Besides, the oil introduced from the oil introduction portion 18 of the bottom plate 4 flows through the plate oil flow passages 7. As a whole, the oil flows within the heat exchanger section 2 in a direction perpendicular to the stacking direction of the core plates. Then, the oil reaches the oil discharge portion 19 of the bottom plate 4.
As shown in
As shown in
Accordingly, constant clearances (gaps) which are the plate oil flow passages 7 and the plate coolant flow passages 8 are formed between the first core plates 5 and the second core plates 6, by alternatingly combining the first core plates 5 and the second core plates 6.
Each of the boss portions 21 around one of the oil through holes 11 of one of the first core plates 5 is joined to one of the boss portions 24 around the one of the oil through holes 11 of one of the second core plates 6 which is adjacent to the one of the first core plates 5. With this, the two plate oil flow passages 7 which are adjacent to each other in the upward and downward directions are connected to each other. Moreover, the adjacent two plate oil flow passages 7 are separated from the plate coolant flow passage 8 between the adjacent two plate oil flow passages 7. Accordingly, in a state where the plurality of the first core plates 5 and the second core plates 6 are joined with each other, the plate oil flow passages 7 are connected with each other through the plurality of the oil through holes 11.
Each of the boss portions 25 around one of the coolant through holes 12 of one of the second core plates 6 is joined to one of the boss portions 22 around one of the coolant through holes 12 of one of the first core plates 5 which is adjacent to the one of the second core plates 6. With this, the two plate coolant flow passages 8 which are adjacent to each other in the upward and downward directions are connected to each other. Moreover, the adjacent two plate coolant flow passages 8 are separated from the plate oil flow passage 7 between the adjacent two plate coolant passages 8. Accordingly, in a state where the plurality of the first core plates 5 and the second core plates 6 are joined with each other, the plate coolant flow passages 8 are connected with each other through the plurality of the coolant through holes 12.
Each of the boss portions 23 around one of the through holes 13 of one of the first core plates 5 is joined to one of the boss portions 26 around one of the through holes 13 of the upper and lower second core plates 6 which are adjacent to the one of the first core plates 5. Accordingly, in this embodiment, in a state where the plurality of the first core plates 5 and the plurality of the second core plates 6 are joined to each other, the through holes 13 are not connected to the plate oil flow passages 7 and the plate coolant flow passages 8.
Besides, a symbol 27 in
Each of the first fin plates 9 has a substantially rectangular outer profile including a pair of longitudinal sides 9a confronting each other; and a pair of lateral sides 9b confronting each other.
As shown in
In a case where a first reference line L1 and a second reference line L2 are defined as lines which pass through a center of the fin plate in a plane of one of the first fin plates 9, and which are perpendicular to each other in the plane of the one of the first fin plates 9, each of the first fin plates 9 has an anisotropy (anisotropism) in which a flow resistance in a direction parallel to the first reference line L1 is smaller than a flow resistance in a direction parallel to the second reference line L2. That is, each of the first fin plates 9 has an anisotropy in which a flow resistance in a direction parallel to the lateral side 9b is greater than a flow resistance in a direction parallel to the longitudinal side 9a.
Each of the first fin plates 9 is formed so that the both ends (upper and lower ends in
That is, each of the second core plates 6 includes rectangular regions each of which is adjacent to one of the lateral sides 9b of the first fin plate 9, and each of which is not covered with the first fin plate 9. Each of the oil through holes 11 and each of the coolant through holes 12 are positioned at one of these rectangular regions. That is, the two oil through holes 11 are positioned to sandwich the first fin plate 9 in a direction along the first reference line L1 The two coolant through holes 12 are positioned to sandwich the first fin plate 9 in a direction along the first reference line L1. Accordingly, in this embodiment, in the plate oil flow passage 7, it is possible to produce a substantially uniform flow of the oil which flows in a in a direction parallel to the first reference line L1 of the first fin plate 9, and which is uniform in the second reference line L2, by the first fin plate 9.
The first fin plate 9 is explained in detail with reference to
As shown in
As shown in
Each of the foot portions 33 of the first fin plate 9 includes reference walls 33a, first protruding walls 33b each protruding toward one of the foot portions 33 which are adjacent to the reference wall 33a in the Y direction; and second protruding walls 33c each protruding toward the other of the foot portions 33 which are adjacent to the reference wall 33a in the Y direction. One of the first protruding walls 33b and one of the second protruding walls 33c are positioned on both sides of one of the reference walls 33b in the X direction. Two of the reference walls 33a are positioned on both sides of one of the first protruding walls 33b. Moreover, two of the reference walls 33a are positioned on both sides of the second protruding walls 33c. In this embodiment, each of the foot portions 33b is formed so as to repeat an order of the reference wall 33a, the second protruding wall 33c, the reference wall 33a, and the first protruding wall 33b in the X direction.
Moreover, each of the foot portions 33 of one of the first fin plates 9 includes stepped walls 34 formed at a predetermined interval along one of the top walls 31 and one of the bottom walls 32. Each of the stepped walls 34 is a stepped surface between one of the reference walls 33a and one of the first protruding walls 33b, or a stepped surface between one of the reference walls 33a and one of the second protruding walls 33c. Accordingly, each of the foot portions 33 is formed into a rectangular corrugated shape along one of the top walls 31 and one of the bottom walls 32 by the reference walls 33a, the first protruding walls 33b, the second protruding walls 33c, and the stepped walls 34 which are repeatedly formed in the X direction. Each of the stepped walls 34 is formed at a position apart from one of the top walls 31 and one of the bottom walls 32.
Furthermore, each of the foot portions 33 of the first fin plate 9 has the corrugated shape which has the same phase as the phase of one of the foot portions 33 that is adjacent to the each of the foot portions 33 in the Y direction. That is, in two of the foot portions 33 which are adjacent to each other in the Y direction, the reference walls 33a confront the reference walls 33a, the first protruding walls 33b confront the first protruding walls 33b, and the second protruding walls 33c confront the second protruding walls 33c.
Each of the stepped walls 34 of one of the foot portions 33 of the first fin plate 9 includes an elongated opening portion 35 having a width equal to or smaller than a thickness of the first fin plate 9. That is, each of the stepped walls 34 of the foot portion 33 of the first fin plate 9 is a stepped surface in which the elongated opening portion 35 having the width equal to or smaller than a thickness of the first fin plate 9 can be formed.
Each of the opening portions 35 of the first fin plate 9 is an elongated through hole along the X direction. Each of the opening portions 35 of the first fin plate 9 may be, for example, an elongated opening having a width t1 of about 0.1 mm in a case where the first fin plates 9 are used in the oil circuit like this embodiment.
In a case where each of the above-described first fin plates 9 is formed, slits extending in the Y direction are intermittently formed in the base metal at a predetermined interval P1 in the X direction. Then, by bending the base metal along these slits, each of the foot portions 33 of the first fin plate 9 becomes the corrugated shape in the X direction. That is, by bending the base metal along these slits, the stepped walls 34, and the elongated opening portions 35 each having the width equal to or smaller than the thickness of the first fin plate 9 are formed in the first fin plate 9.
Then, the base metal in which the opening portions 35 each having the extremely small passage sectional area are formed is bent at predetermined positions in the opposite directions while being sent in the Y direction. With this, the first fin plate 9 is formed into the V-shaped corrugated shape.
The reference walls 33a, the first protruding walls 33b, and the second protruding walls 33c of each of the first fin plates 9 are arranged (formed) in a line in a broken line shape by the opening portions 35 formed in the foot portion 33. Moreover, the rows of the adjacent walls are in a complement relationship. The entire are arranged in a staggered arrangement (in a zigzag shape).
Accordingly, when the oil flows in the X direction, the oil linearly flows between the rows of the adjacent foot portions 33 as shown by arrows 36, and the oil flows through the opening portions 35. Consequently, a boundary layer is difficult to be generated. Moreover, the passage resistance is small. When the oil flows in the Y direction, the oil cannot linearly flow since the adjacent rows of the foot portions 33 are superimposed. The oil flows meandering as shown by arrows 37. Moreover, the opening portions 35 through which the oil passes when the oil flows in the Y direction has the extremely small passage sectional area. Accordingly, the passage resistance becomes large when the oil flows in the Y direction. That is, each of the first fin plates 9 has an anisotropy (anisotropism) in which the passage resistance in the X direction is different from the passage resistance in the Y direction. The passage resistance to the flow in the X direction (the direction along the above-described first reference line L1) is relatively small. The passage resistance to the flow in the Y direction (the direction along the above-described second reference line L2) is extremely large.
Each of the second fin plates 10 has a substantially rectangular outer profile including a pair of longitudinal sides 10a confronting each other; and a pair of lateral sides 10b confronting each other.
As shown in
In a case where a first reference line L1 and a second reference line L2 are defined as lines which pass through a center of the fin plate in a plane of one of the second fin plates 10, and which are perpendicular to each other in the plane of the one of the second fin plates 10, each of the second fin plates 10 has an anisotropy (anisotropism) in which a flow resistance in a direction parallel to the first reference line L1 is smaller than a flow resistance in a direction parallel to the second reference line L2. That is, each of the second fin plates 10 has an anisotropy in which a flow resistance in a direction parallel to the lateral side 10b is greater than a flow resistance in a direction parallel to the longitudinal side 10a.
Each of the second fin plates 10 is formed so that the both ends (upper and lower ends in
That is, each of the first core plates 5 includes rectangular regions each of which is adjacent to one of the lateral sides 10b of the second fin plate 10, and each of which is not covered with the second fin plate 10. Each of the oil through holes 11 and each of the coolant through holes 12 are positioned at one of these rectangular regions. That is, the two oil through holes 11 are positioned to sandwich the second fin plate 10 in a direction along the first reference line L1. The two coolant through holes 12 are positioned to sandwich the second fin plate 10 in a direction along the first reference line L1. Accordingly, in this embodiment, in the plate coolant flow passage 8, it is possible to produce a substantially uniform flow of the coolant which flows in a in a direction parallel to the first reference line L1 of the second fin plate 10, and which is uniform in the second reference line L2, by the second fin plate 10.
The second fin plate 10 is explained in detail with reference to
As shown in
As shown in
Each of the foot portions 43 of the second fin plate 10 includes first walls 43a, and second walls 43b which is deviated by a predetermined pitch in the Y direction with respect to the first walls 43a. Two of the second walls 43b are positioned on both sides of each of the first walls 43a in the X direction. Two of the first walls 43a are positioned on both sides of each of the second walls 43b in the X direction. In this embodiment, each of the foot portions 43 is formed so as to repeat an order of the first wall 43a, the second wall 43b, the first wall 43a, and second wall 43b in the X direction.
Moreover, each of the foot portions 43 of one of the second fin plates 10 includes stepped walls 44 formed at a predetermined interval along one of the top walls 41 and one of the bottom walls 42. Each of the stepped walls 44 is a stepped wall between one of the first walls 43a and one of the second walls 43b. Accordingly, each of the foot portions 43 is formed into a rectangular corrugated shape along one of the top walls 41 and one of the bottom walls 42 by the first walls 43a, the second walls 43b, and the stepped walls 44 which are repeatedly formed in the X direction. Each of the stepped walls 44 is formed at a position apart from one of the top walls 41 and one of the bottom walls 42.
Furthermore, each of the foot portions 43 of the second fin plate 10 has the corrugated shape which has the same phase as the phase of one of the foot portions 43 that is adjacent to the each of the foot portions 43 in the Y direction. That is, in two of the foot portions 33 which are adjacent to each other in the Y direction, the first walls 43a confront the first walls 43a, and the second walls 43b confront the second walls 43b.
Each of the stepped walk 44 of one of the foot portions 43 of the second fin plate 10 includes an elongated opening portion 45 having a width equal to or smaller than a thickness of the second fin plate 10. That is, each of the stepped walls 44 of the foot portion 43 of the second fin plate 10 is a stepped surface in which the elongated opening portion 45 having the width equal to or smaller than a thickness of the second fin plate 10 can be formed.
Each of the opening portions 45 of the second fin plate 10 is an elongated through hole along the X direction. Each of the opening portions 45 of the second fin plate 10 may be, for example, an elongated opening having a width is t2 of about 0.15 mm in a case where the second fin plates 10 are used in the coolant circuit like this embodiment.
In a case where each of the above-described second fin plates 10 is formed, slits extending in the Y direction are intermittently formed in the base metal at a predetermined interval P2 in the X direction.
Then, the base metal in which the slits are formed is bent at predetermined positions in the opposite directions while being sent in the Y direction. With this, the second fin plate 10 is formed into the trapezoid corrugated shape. Moreover, the base metal is bent along the slits at the predetermined interval P2 in the X direction to be deviated by the predetermined pitch. With this, the foot portion 43 of the second fin plate 10 is formed into the corrugated shape in the X direction. That is, by bending the base metal along these slits, the stepped walls 44, and the opening portions 45 each having the width equal to or smaller than the thickness of the second fin plate 10 are formed in the second fin plate 10.
The first walls 43a, and the second walls 43c of each of the second fin plates 10 are arranged (formed) in a line in a broken line shape by the opening portions 45 formed in the foot portion 43. Moreover, the rows of the adjacent walls are in a complement relationship. The entire are arranged in a staggered arrangement (in a zigzag shape).
Accordingly, when the coolant flows in the X direction, the coolant linearly flows between the rows of the adjacent foot portions 43 as shown by arrows 46, and the coolant flows through the opening portions 45. Consequently, a boundary layer is difficult to be generated. Moreover, the passage resistance is small. When the coolant flows in the Y direction, the coolant cannot linearly flow since the adjacent rows of the foot portions 43 are superimposed. The coolant flows meandering as shown by arrows 47. Moreover, the opening portions 45 through which the coolant passes when the coolant flows in the Y direction has the extremely small passage sectional area. Accordingly, the passage resistance becomes large when the coolant flows in the Y direction. That is, each of the second fin plates 10 has an anisotropy (anisotropism) in which the passage resistance in the X direction is different from the passage resistance in the Y direction. The passage resistance to the flow in the X direction (the direction along the above-described first reference line L1) is relatively small. The passage resistance to the flow in the Y direction (the direction along the above-described second reference line L2) is large.
Besides, in the above-described embodiment, the first fin plates 9 are disposed, respectively, in the plate oil flow passages 7. The second fin plates 10 are disposed, respectively, in the plate coolant flow passages 8. However, the second fin plates 10 may be disposed, respectively, in the plate oil flow passages 7. The first fin plates 9 may be disposed, respectively, in the plate coolant flow passages 8. Moreover, the first fin plates 9 may be disposed, respectively, in both the plate oil flow passages 7 and the plate coolant flow passages 8. Furthermore, the second fin plates 10 may be disposed, respectively, in both the plate oil flow passages 7 and the plate coolant flow passages 8.
In this embodiment, the direction of the anisotropy of the first fin plate 9 in the plate oil flow passage 7 is identical to the direction of the anisotropy of the second fin plate 10 in the plate coolant flow passage 8. Moreover, the oil introduction portion 18 and the coolant introduction portion 14 are disposed to sandwich the first and second fin plates 9 and 10 in the direction along the first reference line L1 of the first and second fin plates 9 and 10. Accordingly, the oil in each of the plate oil flow passages 7 flows in a direction opposite to the direction of the flow of the coolant of one of the plate coolant flow passages 8. That is, the direction of the substantially flow of the oil which is formed in each of the plate oil flow passages 7 is opposite to the direction of the substantially uniform flow of the coolant which is formed in one of the plate coolant flow passages 8. Specifically, the direction of the flow of the oil in each of the plate oil flow passages 7 is opposite to the direction of the flow of the coolant in the one of the plate coolant flow passages 8, in regions in which the first and second fin plates 9 and 10 are disposed. Moreover, the direction of the flow of the oil in each of the first fin plates 9 is opposite to the direction of the flow of the coolant in one of the second fin plates 10. Accordingly, in the regions in which the first and second fin plates 9 and 10 are disposed, the flow of the oil and the flow of the is coolant become opposed flows (counter flows). Consequently, it is possible to improve the heat exchanger efficiency.
In each of the plate oil flow passages 7, the first fin plate 9 is positioned between the pair of the oil through holes 11. Moreover, each of the plate oil flow passages 7 has the fluid resistance greater than the fluid resistance in one of the plate coolant flow passages 8. Accordingly, in the plate oil flow passage 7, even when the distance S1 between each of the oil through holes 11 and the first fin plate 9 is small as shown in
In each of the plate coolant flow passages 8, the second fin plate 10 is positioned between the pair of the coolant through holes 12. Moreover, each of the plate coolant flow passages 8 has the fluid resistance smaller than the fluid resistance in one of the plate oil flow passages 7. Accordingly, in the plate coolant flow passage 8, it is necessary to widen the distance S2 between each of the coolant through holes 12 and the second fin plate 10, as shown in
The first fin plate 9 includes the opening portions 35 each of which is formed in one of the stepped walls 34, and each of which has the width equal to or smaller than the thickness of the first fin plate 9. With this, it is possible to relatively decrease the sizes of the stepped portions 34. Specifically, in the first fin plate 9, it is possible to decrease the protruding amounts of the first protruding walls 33b with respect to the reference walls 33a, and the protruding amounts of the second protruding walls 33c with respect to the reference walls 33a.
Accordingly, in the first fin plate 9, it is possible to decrease the bending intervals when the first fin plate 9 is repeatedly bent in the V-shape while being sent in the Y direction. With this, it is possible to increase the heat transfer area (heating area) per unit area of the first fin plate 9.
Moreover, the stepped walls 34 of the first fin plate 9 are formed at positions away from the top walls 31 and the bottom walls 32. Accordingly, in the first fin plate 9, the adjacent foot portions 33 and 33 are difficult to be contacted with each other near the bottom portion wall 32 and the top portion wall 31 in which a gap (distance) of the adjacent foot portions 33 and 33 becomes relatively narrow. Moreover, each of the foot portions 33 of the first fin plate 9 has the corrugated shape which has a phase identical to the phase of one of the foot portions 33 which is adjacent to the each of the foot portions 33 in the Y direction. Consequently, the adjacent foot portions 33 and 33 are hard to be contacted with each other. Therefore, in the first fin plate 9, it is possible to decrease the bending interval when the first fin plate 9 is repeatedly bent into the V-shape while being sent in the Y direction.
Furthermore, the foot portion 33 of the first fin plate 9 has the V-shaped corrugated shape. Accordingly, it is possible to decrease the bending interval while ensuring the interval between the top walls 31 and 31 (the bottom walls 32 and 32) which are adjacent to each other in the Y direction. Consequently, the first fin plate 9 can suppress the clogging of the foreign object. Besides, in a case where the first fin plate 9 is used in the oil circuit like this embodiment, the clearance (gap) between the top portions 31 and 31 (the bottom portion walls 32 and 32) which are adjacent to each other in the Y direction is ensured so that the foreign object having, for example, the diameter of substantially 0.5 mm is not caught in the clearance. Moreover, in a case where the first fin plate 9 is used in the coolant circuit, the clearance (gap) between the top portions 31 and 31 (the bottom portion walls 32 and 32) which are adjacent to each other in the Y direction is ensured so that the foreign object having, for example, the diameter of substantially 1 mm is not caught in the clearance.
The opening portions 35 are formed in each of the foot portions 33 of the first fin plate 9. Accordingly, the boundary layer is difficult to be developed on the surface of the each of the foot portions 33. Consequently, it is possible to suppress the decrease of the heat exchanger efficiency.
The second fin plate 10 includes the opening portions 45 each of which is formed in one of the stepped walls 44, and each of which has the width equal to or smaller than the thickness of the second fin plate 10. With this, it is possible to relatively decrease the sizes of the stepped portions 44. Specifically, in the second fin plate 10, it is possible to decrease the protruding amounts of the second walls 43b with respect to the first walls 43a.
Accordingly, in the second fin plate 10, it is possible to decrease the bending intervals when the second fin plate 10 is repeatedly bent in the trapezoid shape while being sent in the Y direction. With this, it is possible to increase the heat transfer area (heating area) per unit area of the second fin plate 10.
Moreover, the stepped walls 44 of the second fin plate 10 are formed at positions away from the top walls 41 and the bottom walls 42. Accordingly, in the second fin plate 10, the adjacent foot portions 43 and 43 are difficult to be contacted with each other near the bottom portion wall 42 and the top portion wall 41 in which a gap (distance) of the adjacent foot portions 43 and 43 becomes relatively narrow. Moreover, each of the foot portions 43 of the second fin plate 10 has the corrugated shape which has a phase identical to the phase of one of the foot portions 43 which is adjacent to the each of the foot portions 43 in the Y direction. Consequently, the adjacent foot portions 43 and 43 are hard to be contacted with each other. Therefore, in the second fin plate 10, it is possible to decrease the bending interval when the second fin plate 10 is repeatedly bent into the trapezoid shape while being sent in the Y direction.
Furthermore, the foot portion 43 of the second fin plate 10 has the trapezoid corrugated shape. Accordingly, it is possible to suppress the clogging of the foreign object by ensuring the interval between the top walls 41 and 41 (the bottom walls 42 and 42) which are adjacent to each other in the Y direction. Besides, in a case where the second fin plate 10 is used in the coolant circuit like this embodiment, the clearance (gap) between the top portions 41 and 41 (the bottom portion walls 42 and 42) which are adjacent to each other in the Y direction is ensured so that the foreign object having, for example, the diameter of substantially 1 mm is not caught in the clearance. Moreover, in a case where the second fin plate 9 is used in the coolant circuit, the clearance (gap) between the top portions 41 and 41 (the bottom portion walls 42 and 42) which are adjacent to each other in the direction is ensured so that the foreign object having, for example, the diameter of substantially 0.5 mm is not caught in the clearance.
The opening portions 45 are formed in each of the foot portions 43 of the second fin plate 10. Accordingly, the boundary layer is difficult to be developed on the surface of the each of the foot portions 43. Consequently, it is possible to suppress the decrease of the heat exchanger efficiency.
Next, a second embodiment is explained. Besides, the same symbols are added to the constituting elements which are identical to those of the first embodiment. The repetitive explanations are omitted.
An oil cooler 48 which is a heat exchanger according to a second embodiment of the present invention is explained with reference to
In the second embodiment, the oil cooler 48 has a structure substantially identical to that of the above-described first embodiment. However, the plate coolant flow passage 8 is provided with the plurality of protrusions 49, in place of the second fin plates 10.
The protrusions 49 extends in a direction parallel to the first reference line L1 of the first fin plate 9. The protrusions 49 includes first protruding portions 49a of the first core plate 5, and second protruding portions 49b of the second core plate 6.
Specifically, as shown in
As shown in
In this second embodiment, tip ends of the first protruding portions 49a and the second protruding portions 49b are connected by brazing. A plurality of elongated water passages are formed between the protrusions 49 in the plate coolant flow passage 8. Each of the elongated water passages are independently provided. Each of the elongated water passages extends in a direction parallel to the first reference line L1 of the first fin plate 9.
When the oil cooler 48 is viewed in a planner view, the protrusions 48 are provided in a region in which the protrusions 49 is superimposed with the first fin plate 9 of the plate coolant flow passage 8. That is, the protrusions 49 are formed in a region in which the protrusions 49 are superimposed with the region in which the first fin plate 9 is disposed.
In this oil cooler 48 according to the second embodiment, it is possible to form the flow substantially parallel to the first reference line L1 within the plate oil flow passage and the plate coolant flow passage, by the first fin plate 9 and the protrusions 49. Accordingly, it is possible to form the uniform flow parallel to the first reference line L1 by the first fin plate 9 and the protrusions 49, and thereby to effectively perform the heat exchange by using the entire of the first and second core plates 5 and 6. That is, in the oil cooler 48 according to the second embodiment, it is possible to attain the effects and the operations which are substantially identical to those of the first embodiment.
Moreover, in this second embodiment, it is possible to omit the fin plates of the plate coolant flow passages 8, and thereby to decrease the number of the components relative to the first embodiment.
Besides, the protrusions 49 of the plate coolant flow passage 8 may be constituted only by the first protruding portions 49a. In this case, tip ends of the first protruding portions 49a are connected by the brazing on the flat back surface of the second core plate 6. Moreover, the protrusions 49 of the plate coolant flow passage 8 may be constituted only by the second protruding portions 49b. In this case, tip ends of the second protruding portions 49b are connected by the brazing on the back bottom surface of the flat second core plate 6. In this way, it is possible to attain the effect and the operations which are substantially identical to those of the first embodiment.
Moreover, the protrusions 49 may be provided to the plate oil flow passages 7, in place of the plate coolant flow passages 8. That is, the protrusions 49 may be provided to the plate oil flow passage 7, in place of the first fin plate 9. The second fin plate 10 may be disposed in the plate coolant flow passage 8. In this structure, it is possible to attain the same effects and the same operations which are substantially identical to those of the first embodiment.
In the second embodiment, the protrusions 49 has the corrugated shape in a direction parallel to the first reference line L1 of the first fin plate 9. However, the protrusions 49 may have a linear shape in a direction parallel to the first reference line L1 of the first fin plate 9.
The fin plate used in the oil coolers 1 and 48 described above is not limited to the first and second fin plates 9 and 10. When a first reference line and a second reference line are defined as lines which pass through a center of the fin plate in a plane of the fin plate, and which are perpendicular to each other in the plate of the fin plate, it is optional to employ the structures of the first and second fin plates 9 and 10 as long as the first and second fin plates 9 and 10 has an anisotropy in which the flow resistance in the direction parallel to the first reference line is smaller than the flow resistance in the direction parallel to the second reference line.
For example, a below-described third fin plate 50 may be used in place of the first fin plate 9 and the second fin plate 10.
Each of the third fin plates 50 which is the fin plate has a substantially rectangular outer profile including a pair of longitudinal sides 50a confronting each other; and a pair of lateral sides 50b confronting each other.
As shown in
In a case where a first reference line L1 and a second reference line L2 are defined as lines which pass through a center of the fin plate in a plane of one of the third fin plates 50, and which are perpendicular to each other in the plane of the one of the third fin plates 50, each of the third fin plates 50 has an anisotropy (anisotropic) in which a flow resistance in a direction parallel to the first reference line L1 is smaller than a flow resistance in a direction parallel to the second reference line L2. That is, each of the third fin plates 50 has an anisotropy in which a flow resistance in a direction parallel to the lateral side 50b is greater than a flow resistance in a direction parallel to the longitudinal side 50a.
Each of the third fin plates 50 is formed so that the both ends (upper and lower ends in
That is, each of the second core plates 6 includes rectangular regions each of which is adjacent to one of the lateral sides 50b of the third fin plate 50, and each of which is not covered with the third fin plate 50. Each of the oil through holes 11 and each of the coolant through holes 12 are positioned at one of these rectangular regions. That is, the two oil through holes 11 are positioned to sandwich the third fin plate 50 in a direction along the first reference line L1. The two coolant through holes 12 are positioned to sandwich the third fin plate 50 in a direction along the first reference line L1. Accordingly, in this example, in the plate oil flow passage 7, it is possible to produce a substantially uniform flow of the oil which flows in a in a direction parallel to the first reference line L1 of the third fin plate 50, and which is uniform in the second reference line L2, by the third fin plate 50.
The third fin plate 50 is explained in detail with reference to
As shown in
As shown in
Each of the foot portions 53 of the third fin plate 50 includes first walls 53a each of which is raised toward one of the foot portions 53 which are adjacent to the each of the foot portions 53 in the Y direction; and second walls 53b each of which is raised toward the other of the foot portions 53 which are adjacent to the each of the foot portions 53 in the Y direction.
The first walls 53a and the second walls 53b are repeatedly alternatingly formed in each of the foot portions 53 of the third fin plate 50 in the X direction.
Moreover, each of the foot portions 53 of one of the third fin plates 50 includes stepped walls 54 formed at a predetermined interval along one of the top walls 51 and one of the bottom walls 52. Each of the stepped walls 54 is a stepped surface between one of the first walls 53a and one of the second walls 53b. Accordingly, each of the foot portions 53 is formed into a rectangular corrugated shape along one of the top walls 53a and one of the bottom walls 53b by the first walls 53a, the second walls 53b, and the stepped walls 54 which are repeatedly formed in the X direction. Each of the stepped walls 54 is formed at a position apart from one of the top walls 51 and one of the bottom walls 52.
Furthermore, each of the foot portions 53 of the third fin plate 50 has the corrugated shape which has the same phase as the phase of the one of the foot portions 53 that is adjacent to the each of the foot portions 53 in the Y direction. That is, in two of the foot portions 53 which are adjacent to each other in the Y direction, the first walls 53a confronts the first walls 53a, and the second walls 53b confronts the second walls 54a.
Each of the stepped walls 54 of one of the foot portions 53 of the third fin plate 50 includes an elongated opening portion 55 having a width equal to or smaller than a thickness of the third fin plate 50. That is, each of the stepped walls 54 of the foot portion 53 of the third fin plate 50 is a stepped surface in which the elongated opening portion 55 having the width equal to or smaller than a thickness of the third fin plate 50 can be formed.
Each of the opening portions 55 of the third fin 50 is an elongated through hole along the X direction. Each of the opening portions 55 of the third fin plate 50 may be, for example, an elongated opening having a width t3 of about 0.1 mm in a case where the third fin plates 50 are used in the oil circuit.
In a case where each of the above-described third fin plates 50 is formed, slits extending in the Y direction are intermittently formed in the base metal at a predetermined interval P3 in the X direction. Then, by bending the base metal along these slits, each of the foot portions 53 of the third fin plate 50 becomes the corrugated shape in the X direction. That is, by bending the base metal along these slits, the stepped walls 54, and the elongated opening portions 55 each having the width equal to or smaller than the thickness of the third fin plate 50 are formed in the third fin plate 50.
Then, the base metal in which the opening portions 55 each having the extremely small passage sectional area are formed is bent at predetermined positions in the opposite directions while being sent in the Y direction. With this, the third fin plate 50 is formed into the V-shaped corrugated shape.
The first walls 53a and the second walls 53b of each of the third fin plates 50 are arranged (formed) in a line in a broken line shape by the opening portions 55 formed in the foot portion 53. Moreover, the rows of the adjacent walls are in a complement relationship. The entire are arranged in a staggered arrangement (in a zigzag shape).
Accordingly, when the oil flows in the X direction, the oil linearly flows between the rows of the adjacent foot portions 53 as shown by arrows 56, and the oil flows through the opening portions 55. Consequently, a boundary layer is difficult to be generated. Moreover, the passage resistance is small. When the oil flows in the Y direction, the oil cannot linearly flow since the adjacent rows of the foot portions 53 are superimposed. The oil flows meandering as shown by arrows 57. Moreover, the opening portions 55 through which the oil passes when the oil flows in the Y direction has the extremely small passage sectional area. Accordingly, the passage resistance becomes large when the oil flows in the Y direction. That is, each of the third fin plates 50 has an anisotropy (anisotropism) in which the passage resistance in the X direction is different from the passage resistance in the Y direction. The passage resistance to the flow in the X direction (the direction along the above-described first reference line L1) is relatively small. The passage resistance to the flow in the Y direction (the direction along the above-described second reference line L2) is extremely large.
In each of the fin plates 3, it is possible to attain the effects and the operations which are identical to those of the first fin plates 9 and the second fin plates 10 described above.
That is, the third fin plate 50 includes the opening portions 55 each of which is formed in one of the stepped walls 54, and each of which the width equal to or smaller than the thickness of the third fin plate 50. With this, it is possible to relatively decrease the sizes of the stepped portions 54. Specifically, in the third fin plate 50, it is possible to decrease the protruding amounts of the second walls 53b with respect to the first walls 53a.
Accordingly, in the third fin plate 50, it is possible to decrease the bending intervals when the third fin plate 50 is repeatedly bent in the V-shape while being sent in the Y direction. With this, it is possible to increase the heat transfer area (heating area) per unit area of the third fin plate 50.
Moreover, the stepped walls 54 of the third fin plate 50 are formed at positions away from the top walls 51 and the bottom walls 52. Accordingly, in the third fin plate 50, the adjacent foot portions 53 and 53 are difficult to be contacted with each other near the bottom portion wall 52 and the top portion wall 51 in which a gap (distance) of the adjacent foot portions 53 and 53 becomes relatively narrow. Moreover, each of the foot portions 53 of the third fin plate 50 has the corrugated shape which has a phase identical to the phase of one of the foot portions 53 which is adjacent to the each of the foot portions 53 in the Y direction. Consequently, the adjacent foot portions 53 and 53 are hard to be contacted with each other. Therefore, in the third fin plate 50, it is possible to decrease the bending interval when the third fin plate 50 is repeatedly bent into the V-shape while being sent in the Y direction.
Furthermore, the foot portion 53 of the third fin plate 50 has the V-shaped corrugated shape. Accordingly, it is possible to decrease the bending interval while ensuring the interval between the top walls 51 and 51 (the bottom walls 52 and 52) which are adjacent to each other in the Y direction. Consequently, the third fin plate 50 can suppress the clogging of the foreign object. Besides, in a case where the third fin plate 50 is used in the oil circuit, the clearance (gap) between the top portions 51 and 51 (the bottom portion walls 52 and 52) which are adjacent to each other in the Y direction is ensured so that the foreign object having, for example, the diameter of substantially 0.5 mm is not caught in the clearance. Moreover, in a case where the third fin plate 50 is used in the coolant circuit, the clearance (gap) between the top portions 51 and 51 (the bottom portion walls 52 and 52) of the foot portion 53 which are adjacent to each other in the Y direction is ensured so that the foreign object having, for example, the diameter of substantially 1 mm is not caught in the clearance.
The opening portions 55 are formed in each of the foot portions 53 of the third fin plate 50. Accordingly, the boundary layer is difficult to be developed on the surface of the each of the foot portions 53. Consequently, it is possible to suppress the decrease of the heat exchanger efficiency.
Specifically, the pair of the oil holes are positioned on a diagonal line of one of the core plates; and the pair of the coolant holes are positioned on a diagonal line of the one of the core plates which is not different from the diagonal line on which the pair of the oil holes are formed.
The fin plates may be disposed, respectively, in the plate oil flow passages and the plate coolant flow passages.
Each of the fin plates may be disposed in one flow passage of the plate oil flow passages and the plate coolant flow passages; and each of the core plates may include a plurality of protrusions each of which extends in a direction parallel to the first reference line within one of the plate flow passages in which one of the fin plates is not disposed.
A direction of a flow of the oil within the plate oil flow passage may be different from a direction of a flow of the coolant within the plate coolant flow passage.
In the present invention, it is possible to form the flow which is parallel to the first reference line in the flow passage between the core plates in which the fin plate is disposed, and which is substantially uniform flow. It is possible to effectively perform the heat exchange by using the entire core plates.
The entire contents of Japanese Patent Application No. 2016-194040 filed Sep. 30, 2016 are incorporated herein by reference.
Although the invention has been described above by reference to certain embodiments of the invention, the invention is not limited to the embodiments described above. Modifications and variations of the embodiments described above will occur to those skilled in the art in light of the above teachings. The scope of the invention is defined with reference to the following claims.
Number | Date | Country | Kind |
---|---|---|---|
2016-194040 | Sep 2016 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4615384 | Shimada et al. | Oct 1986 | A |
4712612 | Okamoto et al. | Dec 1987 | A |
4815532 | Sasaki et al. | Mar 1989 | A |
9921005 | Bluetling | Mar 2018 | B2 |
20020066552 | Komoda | Jun 2002 | A1 |
20030201094 | Evans | Oct 2003 | A1 |
20040177668 | Sagasser | Sep 2004 | A1 |
20040251004 | Stoynoff, Jr. | Dec 2004 | A1 |
20050194123 | Strahle | Sep 2005 | A1 |
20060169445 | Sato et al. | Aug 2006 | A1 |
20070000639 | Ozawa | Jan 2007 | A1 |
20070125527 | Flik | Jun 2007 | A1 |
20090032231 | Komoda | Feb 2009 | A1 |
20120031593 | Uno et al. | Feb 2012 | A1 |
20120205085 | Ariyama | Aug 2012 | A1 |
20150226496 | Cui | Aug 2015 | A1 |
Number | Date | Country |
---|---|---|
11 2013 004 723 | Jun 2015 | DE |
1 211 473 | Jun 2002 | EP |
H08-313183 | Nov 1996 | JP |
2011-7411 | Jan 2011 | JP |
2012-017943 | Jan 2012 | JP |
Entry |
---|
Extended European Search Report, dated Feb. 12, 2018, 6 pages. |
Extended European Search Report, dated Feb. 6, 2018, 7 pages. |
USPTO Office Action, U.S. Appl. No. 15/719,970, dated Jul. 26, 2018, 11 pages. |
USPTO Notice of Allowance, U.S. Appl. No. 15/719,970, dated Dec. 21, 2018, 6 pages. |
Number | Date | Country | |
---|---|---|---|
20180094870 A1 | Apr 2018 | US |