JP4787309B2 - Heat sink assembly - Google Patents

Description

  The present invention relates to a heat sink assembly having a heat sink that is disposed on an integrated circuit mounted on a circuit board and cools the integrated circuit.

Conventionally, a heat sink that releases heat of an integrated circuit such as a CPU (Central Processing Unit) from a cooling fin has been used. Some conventional heat sinks are attached to a circuit board by a plurality of screws and pressed against the integrated circuit by tightening the screws. In such a heat sink, in order to uniformly press the lower surface of the heat sink against the surface of the integrated circuit, it is necessary to balance the tightening degree of the plurality of screws.
JP-A-9-139450

  In the conventional heat sink, it is difficult for an operator to improve workability because the operator needs to balance the tightening degree of the plurality of screws. In particular, when using a heat sink in the inspection process of an integrated circuit, such a screw tightening operation is required every time the integrated circuit to be inspected changes, so the complexity of the operation is a big problem. It was.

  The present invention has been made in view of the above problems, and its object is to suppress the bias of the force acting on the integrated circuit from the lower surface of the heat sink and to improve the workability of the heat sink mounting operation. It is to provide a heat sink assembly that can be used.

  In order to solve the above-described problem, a heat sink assembly according to the present invention has a lower surface capable of contacting an integrated circuit mounted on a substrate, and left and right upper edges positioned above the lower surface. Includes a heat sink provided to be positioned below the upper left and right edge portions. The heat sink assembly is a cam that rotates and presses the heat sink from above, and is arranged so as to face the rotation axis direction at a position away from the rotation axis direction, and can press the upper edge portions. A pair of left and right cams, one or a plurality of levers for rotating the pair of left and right cams, a base member that can be disposed on the substrate, and extending from the base member to rotate the rotation shafts of the pair of left and right cams One or more arms that support it.

  According to the present invention, by operating the lever and rotating the cam, the lower surface of the heat sink can be pressed against the integrated circuit, and the workability of the heat sink mounting operation can be improved. In addition, the lower surface of the heat sink is provided below the left and right upper edge portions, and the pair of left and right cams press the left and right upper edge portions, respectively, thereby suppressing bias in the force acting on the integrated circuit from the lower surface of the heat sink. it can. Furthermore, since the pair of left and right cams are arranged so as to face each other in the direction of the rotation axis at positions separated in the direction of the rotation axis, the number of parts of the heat sink assembly can be reduced. For example, it is possible to reduce the number of parts by sharing the rotation shafts of the pair of left and right cams or by providing separate rotation shafts for each cam while rotating the left and right cams with one lever. .

  In one aspect of the present invention, it further includes a support shaft supported by a base member, the one or more arms are provided to be rotatable about the support shaft, and the pair of left and right cams are Alternatively, the plurality of arms may be provided so as to be movable in a direction approaching or leaving the left and right upper edges. According to this aspect, the heat sink can be easily attached or removed.

  In another aspect of the present invention, the heat sink assembly includes an integrated lever that is attached to each of the pair of left and right cams as the one or more levers, and integrally rotates the pair of left and right cams. May be. According to this aspect, the number of parts of the heat sink assembly can be reduced, and both the left and right cams can be rotated by operating the integrated lever, improving workability when pressing the heat sink against the integrated circuit. it can.

  In this aspect, the heat sink assembly further includes a cooling fan between the left and right upper edge portions, and the integrated lever includes a pair of lever arm portions attached to each of the pair of left and right cams, You may have a connection part which connects a pair of lever arm part. In the state where the pair of left and right cams rotate with the integrated lever and press the heat sink, the pair of lever arm portions and the connecting portion may extend along the side surface of the cooling fan. By doing so, the height of the heat sink assembly can be reduced as compared with the structure in which the lever arrives above the cooling fan after the lever is rotated.

  In another aspect of the present invention, the heat sink assembly may have a common rotation shaft that spans the pair of left and right cams as the rotation shaft of the pair of left and right cams. According to this aspect, the number of parts of the heat sink assembly can be reduced.

  In another aspect of the present invention, the heat sink has a plurality of cooling fins above the lower surface, and the left and right are provided as the one or the plurality of arms so that the plurality of cooling fins are positioned therebetween. You may have a pair of arm. According to this aspect, it is possible to suppress the arm from becoming an obstacle to heat dissipation by the cooling fin.

  Further, in this aspect, the plurality of cooling fins may be arranged side by side with a space therebetween, and the pair of left and right arms may be separated in the direction in which the plurality of cooling fins are arranged. By carrying out like this, it can suppress that the flow of the air which passes between between cooling fins and cools the said cooling fin is inhibited by an arm.

  In another aspect of the present invention, the heat sink may include an adjustment mechanism that adjusts the height of the pair of upper edge portions from the lower surface. According to this aspect, the lower surface of the heat sink can be provided at a height suitable for both of the integrated circuits having different thicknesses.

  In this aspect, the heat sink is a member configured separately from the heat sink body having the lower surface and the heat sink body, and is suspended from the pair of upper edge portions and the pair of upper edge portions, respectively. You may have a heat sink arm which has a pair of side part by which the said heat sink main body is arrange | positioned. The adjustment mechanism includes an adjustment lever attached to the pair of side surface parts so as to be rotatable with respect to the pair of side surface parts, and the adjustment lever is deviated from a center of rotation of the heat sink body. May be supported.

  In another aspect of the present invention, the heat sink may be supported by a heat sink support shaft provided on the base member so as to be openable and closable with respect to the base member. According to this aspect, the workability of the heat sink mounting operation can be improved.

  In this aspect, the heat sink has a heat sink arm supported by the heat sink support shaft and rotatable about the heat sink support shaft, the lower surface, and a supported portion supported by the heat sink arm as an upper portion. A heat sink body, and the base member has a base body that can be disposed on the substrate and a support portion that supports the heat sink support shaft, and the support portion is located above the base body. The heat sink support shaft may be supported at a position away from the center. This makes it possible to reduce the distance between the heat sink support shaft and the supported portion of the heat sink body as compared with the case where the heat sink support shaft is provided at the same height as the base body. As a result, when the lower surface of the heat sink body approaches the integrated circuit from above, it is possible to suppress the position of the lower surface from moving in a direction parallel to the integrated circuit.

  In this case, the heat sink arm may be provided so as to extend from the heat sink support shaft, and the supported portion may be positioned in the extension direction of the heat sink arm with respect to the heat sink support shaft. By doing so, the height of the heat sink support shaft and the height of the supported portion can be made substantially equal, and the distance between the heat sink support shaft and the supported portion of the heat sink body can be made smaller.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view of a heat sink assembly 1 as an example of an embodiment of the present invention, and FIG. 2 is a perspective view of the heat sink assembly 1 with the fan body 61 shown in FIG. 1 removed. FIG. 3 is a perspective view of the heat sink assembly 1 with the cam mechanism 10 and the heat sink 30 opened. FIG. 4 is a side view of the heat sink assembly 1. FIG. 5 is a plan view of the heat sink 30.

  As shown in FIG. 1 or FIG. 3, the heat sink assembly 1 includes a cam mechanism 10, a base member 20 that can be disposed on the circuit board 200, a heat sink 30 that can be disposed on the base member 20, and an upper portion of the heat sink 30. A cooling fan 60 that is attached and sends cooling air to the heat sink 30 is provided. The heat sink 30 and the cam mechanism 10 are disposed on opposite sides of the base member 20.

  Further, the heat sink assembly 1 is provided with a heat sink support shaft 25 and an arm support shaft 24 arranged in parallel to each other, and these shafts are also arranged on opposite sides of the base member 20. The heat sink 30 is provided so as to be rotatable about the heat sink support shaft 25, and the cam mechanism 10 is provided so as to be rotatable about the arm support shaft 24. The heat sink 30 and the cam mechanism 10 are respectively attached to the base member 20. It can be opened and closed. The lower surface 42a of the heat sink 30 is in contact with the integrated circuit 201 mounted on the circuit board 200 in a state where the heat sink 30 is closed (arranged on the base member 20). The heat sink 30 disposed above can be pushed down.

  The heat sink assembly 1 is a heat sink assembly used in, for example, an inspection process of an integrated circuit disposed on a circuit board. By opening the heat sink 30 and the cam mechanism 10, the integrated circuit to be inspected is replaced. It is done.

  As shown in FIG. 3, the base member 20 has a base body 21 that has a rectangular frame shape surrounding the integrated circuit 201. Mounting holes 21 a are formed at four corners of the base body 21, and bolts for fixing the base body 21 on the circuit board 200 are fitted into the mounting holes 21 a.

  Moreover, the base member 20 has a pair of support plates 23 and 23 which face in the left-right direction (direction shown by Dw). The support plates 23 and 23 are attached to the base body 21 so as to sandwich the base body 21. That is, the support plates 23 and 23 are attached to two side surfaces located on opposite sides of the four side surfaces of the base body 21. The arm support shaft 24 is disposed along the side surface 21b perpendicular to the two side surfaces to which the support plates 23 and 23 are attached. The heat sink support shaft 25 supports the arm with the base body 21 in between in the plan view of the heat sink assembly 1. It is arranged on the opposite side to the shaft 24. The arm support shaft 24 and the heat sink support shaft 25 are arranged so as to extend in the left-right direction, and are stretched over the left and right support plates 23. That is, as shown in FIG. 3 or FIG. 4, both end portions of the arm support shaft 24 are fitted in through holes formed in the front end 23a of the support plate 23 so that movement in the axial direction is restricted. It is attached to the front end 23a. Similarly, both ends of the heat sink support shaft 25 are fitted into through holes formed in the rear end 23b of the support plate 23, and are attached to the rear end 23b so that movement in the axial direction is restricted.

  The cam mechanism 10 will be described. As shown in FIG. 3, the cam mechanism 10 includes a common rotating shaft 11, a pair of left and right cams 12 </ b> L and 12 </ b> R that rotate around the common rotating shaft 11 and press the heat sink 30 from above, and the common rotating shaft 11. It has a pair of left and right support arms 13L, 13R to support, and an integrated lever 14 that is operated by an operator to rotate the left and right cams 12L, 12R.

  As shown in FIG. 1 or FIG. 4, the support arms 13 </ b> L and 13 </ b> R are arranged so as to sandwich the base member 20, and extend from the arm support shaft 24 in the radial direction of the arm support shaft 24. The base ends 13a of the support arms 13L and 13R are located outside the front ends 23a of the pair of support plates 23 and 23, and the support arms 13L and 13R are separated in the left-right direction (direction indicated by Dw). Arm support shafts 24 are fitted to the base end portions 13a of the support arms 13L and 13R, and the support arms 13L and 13R are rotatable about the arm support shaft 24. As a result, the cam mechanism 10 can be opened and closed with respect to the base member 20. A stopper 13c that limits the rotation angle of the support arms 13L and 13R is formed at the base end portion 13a of the support arms 13L and 13R. Specifically, the base end portions 13a of the support arms 13L and 13R are located outside the support plate 23, and the stopper 13c protrudes inward from the base end portion 13a. The support arms 13L and 13R are allowed to rotate in the direction in which the cam mechanism 10 opens (the direction in which the left and right cams 12L and 12R separate from the heat sink 30) until the stopper 13c contacts the front end 23a of the support plate 23. .

  As shown in FIG. 1 or FIG. 3, the common rotation shaft 11 is arranged in parallel with the arm support shaft 24 at a position away from the arm support shaft 24. Each of the support arms 13L and 13R extends from a base end portion 13a on which the arm support shaft 24 is fitted, and supports the common rotary shaft 11 rotatably by the tip end portion 13b. Both end portions of the common rotating shaft 11 are fitted into through holes formed in the tip portions 13b of the support arms 13L and 13R, and are attached to the tip portion 13b so as to be restricted from moving in the axial direction.

  The left and right cams 12L and 12R are disposed inside the front end portions 13b of the left and right support arms 13L and 13R (center side in the left and right direction). The cam 12 </ b> L and the cam 12 </ b> R are arranged at positions separated from each other in the axial direction (left-right direction) of the common rotation shaft 11 that is their rotation shaft, and face the axial direction of the common rotation shaft 11. The cam 12L and the cam 12R are substantially rectangular parallelepiped members and are arranged in parallel to each other. FIG. 6 is a side view of the cam 12L and the integrated lever 14 obtained when facing the VI direction shown in FIG. As shown in the figure, the cam 12L is formed with a hole 12a penetrating in the left-right direction (the thickness direction of the cam 12L). A similar hole is formed in the cam 12R. And the common rotating shaft 11 is inserted in these holes 12a, and is spanned over the left and right cams 12L and 12R (see FIG. 1). The left and right cams 12L and 12R are rotatable in the same direction around the common rotation shaft 11. As described above, the left and right cams 12L and 12R are arranged apart from each other in the axial direction, and are arranged so as to face each other, thereby rotating the two cams 12L and 12R around the common rotation shaft 11. Therefore, the number of parts of the heat sink assembly 1 can be reduced.

  As shown in FIG. 6, the cam 12 </ b> L has a pressing surface 12 b positioned in the radial direction of the common rotating shaft 11 and a slide surface 12 c adjacent to the pressing surface 12 b with respect to the common rotating shaft 11. Yes. A distance L1 from the center C of the common rotating shaft 11 to the pressing surface 12b is larger than a distance L2 from the center C of the common rotating shaft 11 to the slide surface 12c. The slide surface 12c is curved so as to suppress an increase in the distance from the center C to the slide surface 12c as it approaches the pressing surface 12b. The cam 12R has the same shape as the cam 12L, and the pressing surface 12b and the slide surface 12c are also formed on the cam 12R.

  As shown in FIG. 3, the integrated lever 14 has a pair of lever arm portions 14L and 14R that are spaced apart in the left-right direction and are attached to the left and right cams 12L and 12R, respectively. The lever arm portions 14L and 14R are elongated plate-like members extending from the base end portion 14a in the radial direction of the common rotating shaft 11. The base end portion 14a is attached to the left and right cams 12L and 12R so that the integral lever 14 cannot rotate relative to the left and right cams 12L and 12R. That is, the lever arm portions 14L and 14R are attached to the cams 12L and 12R so that the lever arm portions 14L and 14R rotate together with the left and right cams 12L and 12R.

  In the example described here, the base end portion 14a of the lever arm portions 14L and 14R is provided with a protrusion 14b protruding in the radial direction of the common rotating shaft 11, and the protrusion 14b is fitted to the cams 12L and 12R. (See FIG. 6). A bolt 19 provided at a position radially away from the common rotating shaft 11 is fitted in both the cams 12L and 12R and the base end portion 14a in the axial direction of the common rotating shaft 11 (FIG. 3). reference). Further, the cams 12L and 12R are formed with protrusions 12d protruding in the axial direction, and the protrusions 12d are fitted in holes formed in the base end portions 14a of the lever arm portions 14L and 14R (see FIG. 6). As a result, the relative rotation of the integrated lever 14 with respect to the left and right cams 12L, 12R is restricted.

  The rotation angle of the integrated lever 14 with respect to the support arms 13L and 13R is limited by the bolt 19. That is, until the head of the bolt 19 contacts the support arms 13L and 13R, the integral lever 14 is allowed to rotate in the direction away from the heat sink 30 (the direction in which the cam mechanism 10 opens) around the common rotation shaft 11. (See FIG. 3). As described above, by limiting the rotation angle of the integrated lever 14 and the support arms 13L and 13R, interference between the devices arranged around the integrated circuit 201 and the heat sink assembly 1 is suppressed.

  As shown in FIG. 3, the lever arm portions 14 </ b> L and 14 </ b> R are connected by a connecting bar 14 c extending in the left-right direction, and rotate the left and right cams 12 </ b> L and 12 </ b> R around the common rotating shaft 11. That is, the integrated lever 14 is operated by an operator and rotates the left and right cams 12L and 12R simultaneously. As described above, the left and right cams 12L and 12R are arranged apart from each other in the axial direction and are arranged so as to face each other, so that both the left and right cams 12L and 12R are rotated by one integrated lever 14. The number of parts of the heat sink assembly 1 can be reduced.

  In this example, the tip ends of the lever arm portions 14L and 14R are connected by a connecting bar 14c, and the integrated lever 14 has a frame shape lacking one side. The lever arm portions 14L and 14R and the connecting bar 14c are integrally formed. For example, the frame-like integrated lever 14 lacking one side is formed by bending the elongated plate material.

  The operation of the cam mechanism 10 will be described. As described above, the support arms 13L and 13R are rotatably provided around the arm support shaft 24, and the left and right cams 12L and 12R move in the circumferential direction around the arm support shaft 24. As a result, when the heat sink 30 is closed, the left and right cams 12L and 12R approach the left and right upper edge portions 32L and 32R provided on the heat sink 30 to be described later, or move away from the upper edge portions 32L and 32R. (See FIG. 1 or FIG. 5). The left and right support arms 13L and 13R support the common rotating shaft 11 spanned between the cams 12L and 12R, and the left and right cams 12L and 12R move integrally.

  Note that the left and right support arms 13L and 13R may be connected by a member extending in the left-right direction. In place of the common rotating shaft 11, the left and right cams 12L and 12R are provided with rotating shafts for separately supporting the cams 12L and 12R, and these rotating shafts are supported by the left and right support arms 13L and 13R. It may be supported. Even with such a structure, the left and right cams 12L and 12R integrally move in the circumferential direction around the arm support shaft 24.

  When the support arms 13L and 13R rotate upward (in the direction of closing the cam mechanism 10), the left and right cams 12L and 12R are disposed above the upper edges 32L and 32R, respectively, and the slide surface 12c is positioned at the upper edges 32L and 32R. Face each other. In the heat sink assembly 1 described here, the positions pressed by the cams 12L and 12R are the tips of the upper edge portions 32L and 32R, and the tips are positioned above the arm support shaft 24 when the heat sink 30 is closed. To do. Therefore, when the left and right cams 12L and 12R are arranged above the upper edge portions 32L and 32R, the support arms 13L and 13R are arranged in the vertical direction with respect to the base body 21. At this time, the common rotating shaft 11 is disposed above the front upper edge portion 32a that connects the left and right upper edge portions 32L and 32R (see FIG. 1 or FIG. 5).

  Thereafter, when the integrated lever 14 is rotated in a direction to close the cam mechanism 10 (a direction approaching the upper edge portions 32L, 32R), the left and right cams 12L slide while the slide surface 12c slides with respect to the upper edge portions 32L, 32R. , 12R rotate on the upper edges 32L, 32R. The cams 12L and 12R rotate until the pressing surface 12b faces the upper edge portions 32L and 32R and pushes down the upper edge portions 32L and 32R. At this time, the lever arm portions 14L and 14R of the integrated lever 14 are disposed substantially perpendicular to the support arms 13L and 13R above the upper edge portions 32L and 32R, and are rearward along the upper edge portions 32L and 32R ( (Direction shown by Dr) (see FIG. 1).

  The heat sink 30 will be described. 7 is a side view of the heat sink 30, FIG. 8 is a view showing the heat sink 30 exploded in the up-down direction, and FIG. 9 is a view showing the heat sink 30 exploded in the left-right direction. 10 is a cross-sectional view taken along line XX shown in FIG.

  As shown in FIG. 8, the heat sink 30 has a heat sink body 40. The heat sink body 40 includes a fin assembly 41 having a plurality of fins 41a and a fin cover 45 covering the plurality of fins 41a (see FIG. 2).

  The fin assembly 41 has a rectangular parallelepiped lower base 42 that is positioned below the fin assembly 41. The lower base 42 is disposed inside the base body 21 when the heat sink 30 is closed. When the heat sink 30 is used, the lower surface 42a of the lower base 42 contacts the surface of the integrated circuit 201 (see FIG. 3). The fin assembly 41 has a plate-like upper base 43 that is fixed to the upper surface of the lower base 42 and is larger than the lower base 42. As shown in FIG. 2, a plurality of fins 41 a having a plate shape are erected on the upper surface of the upper base 43. The plurality of fins 41 a are arranged on the upper base 43 in the left-right direction at intervals.

  Further, as shown in FIG. 2, the plurality of fins 41a are provided so as to be positioned between the left and right support arms 13L and 13R described above. Specifically, as described above, the base ends 13a of the support arms 13L and 13R are positioned outside the left and right support plates 23, and the plurality of fins 41a are disposed between the left and right support plates 23. 21 is located above. Further, since the plurality of fins 41a are arranged in the left-right direction at intervals, and the support arms 13L, 13R are also arranged apart in the left-right direction, the support arms 13L, 13R are arranged in the arrangement direction of the plurality of fins 41a. is seperated. Thus, the cooling air that has passed between the plurality of fins 41a flows between the left and right support arms 13L and 13R and flows to the outside of the heat sink assembly 1.

  As shown in FIG. 5 or FIG. 8, the fin cover 45 is disposed so as to cover the fin assembly 41 from above. The fin cover 45 has a rectangular frame shape in plan view, and a plurality of fins 41 a are exposed upward from the inside of the fin cover 45. The fin cover 45 has a substantially rectangular upper edge 45a arranged so as to surround the plurality of fins 41a in a plan view of the heat sink 30 (see FIG. 5). The upper edge portion 45a is located upward from the fin assembly 41 (see FIG. 10), and the lower surface 42a of the fin assembly 41 is located below the center of the upper edge portion 45a. The upper edge portion 45a has a pair of upper right edge portion 45ar and left upper edge portion 45al located on opposite sides of the fin assembly 41. The upper right edge portion 45ar and the upper left edge portion 45al are arranged in the front-rear direction (Df-Dr Direction). Also, the fin cover 45 is provided with a pair of side surfaces 45d that hang from the upper right edge 45ar and the upper left edge 45al and face in the left-right direction, and a plurality of fins 41a are disposed between the pair of side surfaces 45d. (See FIG. 8 and FIG. 10).

  The heat sink body 40 is configured so that the upper edge 45a approaches the fin assembly 41 when the downward force is applied to the fin cover 45, that is, the distance between the fin cover 45 and the lower surface 42a is reduced. ing. In this example, as shown in FIG. 8, the heat sink body 40 has a compression spring 46 and a bolt 47. The fins 41a are not disposed at the four corners of the upper base 43 of the fin assembly 41, and the compression springs 46 are disposed between the four corners of the upper base 43 and the four corners of the upper edge portion 45a. The compression spring 46 is urged in a direction that widens the distance between the upper base 43 and the upper edge 45a. The bolts 47 are fitted in holes formed at the four corners of the upper edge 45a (see FIG. 5). The bolt 47 is disposed inside the compression spring 46 and defines the position of the compression spring 46. In the bolt 47, a screw is formed only at the tip 47 a, and the tip 47 a is fixed to the four corners of the upper base 43. When a downward force is applied to the fin cover 45, the upper edge portion 45a moves downward relative to the bolt 47 while compressing the compression spring 46, whereby the distance between the fin cover 45 and the lower surface 42a is increased. It narrows.

  As described above, the heat sink assembly 1 is provided with the cooling fan 60. As shown in FIG. 1, the cooling fan 60 is disposed between a fan body 61 having a plurality of blades 61 a that rotate above the heat sink body 40, and the upper edge 45 a of the fan body 61 and the fin cover 45. A cylindrical fan base 62 that supports the fan body 61 is provided above the heat sink body 40. The cooling fan 60 is attached to the heat sink body 40 by four bolts 63. Specifically, the bolt 63 is provided at a position corresponding to the bolt 47, and the tip of the bolt 63 is fixed to a bolt hole 47b formed in the head of the bolt 47 (see FIG. 5).

  The cooling fan 60 has a substantially square shape in plan view, and the integrated lever 14 described above has a shape corresponding to the outer shape of the cooling fan 60. That is, the integrated lever 14 has a frame shape lacking one side. Therefore, when the integrated lever 14 is operated by the operator and the cams 12L and 12R press the upper edge portions 32L and 32R downward, the lever arm portions 14L and 14R are in the front-rear direction (direction indicated by Df-Dr). The integrated lever 14 and the common rotating shaft 11 surround the side surface of the cooling fan 60. That is, the lever arm portions 14 </ b> L and 14 </ b> R, the connecting bar 14 c, and the common rotating shaft 11 extend along the side surface of the fan base 62. In this example, in a state where the heat sink 30 and the cam mechanism 10 are closed, the integrated lever 14 and the common rotating shaft 11 are disposed at a position lower than the fan main body 61.

  As shown in FIG. 8, the heat sink 30 is configured separately from the heat sink body 40 and includes a heat sink arm 31 that supports the upper portion of the heat sink body 40. Since the heat sink arm 31 is rotatably supported by the heat sink support shaft 25, the heat sink 30 can be opened and closed with respect to the base member 20 (see FIG. 3).

  As shown in FIG. 5, the heat sink arm 31 has a frame shape surrounding the heat sink body 40. The heat sink arm 31 has an upper edge portion 32 that is located above the heat sink body 40 and is disposed so as to cover the fin cover 45 (see FIG. 10). The upper edge portion 32 has a pair of left and right upper edge portions 32L and 32R located on opposite sides of the heat sink body 40. The upper edge portions 32L and 32R have an elongated plate shape that extends in the front-rear direction with the heat sink 30 closed. The upper edge portion 32 is provided at a position away from the lower surface 42a of the heat sink main body 40, and the lower surface 42a is located between the left and right upper edge portions 32L and 32R. As described above, the upper edge portions 32L and 32R are pressed by the left and right cams 12L and 12R. Therefore, it is possible to suppress the bias of the force acting on the surface of the integrated circuit 201 from the lower surface 42a. That is, the force acting on the right side of the integrated circuit 201 and the force acting on the left side can be balanced. In particular, in the present embodiment, the lower surface 42 a is located below the center of the upper edge portion 32.

  When the heat sink 30 is closed, the upper edge portions 32L and 32R are arranged substantially parallel to the circuit board 200 (see FIG. 4). When the support arms 13L and 13R rotate around the arm support shaft 24, the left and right cams 12L and 12R are disposed above the tips of the left and right upper edge portions 32L and 32R. A thin plate-like pressed plate 39 is attached to the tips of the left and right upper edge portions 32L, 32R (see FIGS. 5 and 7). The left and right cams 12L and 12R press the tips of the upper edge portions 32L and 32R from above with the pressed plate 39 sandwiched between the upper edge portions 32L and 32R (see FIG. 1). The left and right upper edge portions 32L and 32R are connected by a front upper edge portion 32a and a rear upper edge portion 32b that extend in the left-right direction and are located on opposite sides of the heat sink body 40 (see FIG. 5). .

  The heat sink arm 31 has a pair of side surfaces 33L and 33R that hang from the left and right upper edge portions 32L and 32R and face each other in the left and right direction (see FIGS. 3 and 10). The upper portion of the heat sink body 40 is disposed between the side surface portions 33L and 33R. In this example, the side surface portion 45d of the fin cover 45 is located inside the side surface portions 33L and 33R.

  The heat sink support shaft 25 is stretched between the base end portions 33a of the left and right side surface portions 33L and 33R, and the side surface portions 33L and 33R extend from the base end portion 33a in the radial direction of the heat sink support shaft 25 (FIG. 4). reference). Specifically, a hole penetrating in the left-right direction is formed in the base end portion 33a of the side surface portions 33L and 33R. Both ends of the heat sink support shaft 25 are fitted into the holes and attached to the base end portion 33a so that movement in the axial direction is restricted. As a result, the heat sink arm 31 is rotatable about the heat sink support shaft 25.

  As shown in FIG. 1 or FIG. 5, the base end portion 33a is disposed outside the support plate 23, and the base end portion 33a is provided with a stopper 33b protruding inward. The rotation angle of the heat sink arm 31 is limited by the stopper 33b. That is, the heat sink arm 31 is allowed to rotate in the opening direction with respect to the base member 20 until the stopper 33b hits the rear end 23b of the support plate 23. As described above, the rotation angle of the heat sink arm 31 is limited, so that interference between the device arranged around the integrated circuit 201 and the heat sink 30 is suppressed.

  The heat sink arm 31 supports the heat sink main body 40 via adjustment levers 35 and 35 attached to the center in the front-rear direction of the side portions 33L and 33R and a main body support shaft 36 extending in the left-right direction (FIG. 5). Or refer to FIG. Specifically, as shown in FIG. 10, attachment holes 33 c having an inner diameter larger than the diameter of the main body support shaft 36 are formed in the side surfaces 33 </ b> L and 33 </ b> R. The adjustment lever 35 has an attachment portion 35a having an outer diameter corresponding to the inner diameter of the attachment hole 33c on the side surface portions 33L and 33R, and the attachment portion 35a is fitted in the attachment hole 33c. The adjustment lever 35 is formed with a support hole 35b penetrating in the left-right direction, and both ends of the main body support shaft 36 are fitted into the support hole 35b. Further, a supported hole 45e penetrating the side surface 45d in the left-right direction is formed in the side surface portion 45d of the fin cover 45 located inside the side surface portions 33L and 33R. It is also fitted in the hole 45e.

  Thus, the heat sink arm 31 supports the heat sink body 40 in a state where the heat sink body 40 is suspended from above by the body support shaft 36. Accordingly, even when the heat sink arm 31 is slightly inclined in a state where the heat sink 30 is closed, the heat sink body 40 is slightly rotated around the main body support shaft 36, and the heat sink arm 31 is moved to the heat sink arm 31. The lower surface 42 a is disposed in parallel to the surface of the integrated circuit 201 by being inclined relative to the integrated circuit 201.

  When the left and right upper edge portions 32L, 32R are pressed by the cams 12L, 12R, the force is transmitted from the heat sink arm 31 to the fin assembly 41 through the main body support shaft 36, the fin cover 45, and the compression spring 46. . The body support shaft 36 is disposed above the center of the lower surface 42a of the heat sink body 40 in the front-rear direction. Therefore, the force acting on the front side of the surface of the integrated circuit 201 from the lower surface 42a can be balanced with the force acting on the rear side.

  Further, the heat sink arm 31 has an adjustment mechanism that adjusts the height from the lower surface 42 a of the upper edge portion 32 using the adjustment lever 35. FIG. 11 is a side view of the heat sink arm 31 for explaining this adjustment mechanism, in which C1 indicates the position of the rotation center of the adjustment lever 35, and C2 indicates the position of the center line of the main body support shaft 36. Is shown.

  The attachment portion 35a of the adjustment lever 35 is circular and is attached so as to be rotatable with respect to the attachment holes 33c of the side surface portions 33L and 33R. The adjustment lever 35 supports the heat sink body 40 at a position deviated from the rotation center C1. That is, as shown in FIG. 10 or FIG. 11, the support hole 35 b described above is provided at a position offset from the rotation center C <b> 1 of the adjustment lever 35. Therefore, as shown in FIG. 11, when the adjustment lever 35 rotates, the center line C2 of the main body support shaft 36 and the height of the fin cover 45 change, whereby the upper edge portions 32L and 32R of the heat sink main body 40 are changed. The height from the lower surface 42a changes.

  In this example, the tip of the adjustment lever 35 is provided with a projection 35c that protrudes toward the side surfaces 33L and 33R (see FIG. 9). On the other hand, on the side surfaces 33L and 33R, two locking holes 33d and 33e into which the projections 35c are fitted are formed on the tracks of the projections 35c when the adjustment lever 35 rotates. Accordingly, the adjustment lever 35 is supporting the main body support shaft 36 at a position lower than the rotation center C1 (hereinafter referred to as a low position) (the center line C2 is lower than the rotation center C1), and the adjustment lever 35 is the rotation center. In a state where the main body support shaft 36 is supported at a position higher than C1 (hereinafter referred to as a high position) (a state where the center line C2 is higher than the rotation center C1), the rotation position of the adjustment lever 35 stops. That is, when the projection 35c is fitted in the locking hole 33d, the main body support shaft 36 is supported at a low position, and when the projection 35c is fitted in the locking hole 33e, the main body support shaft 36 is supported at a high position. Is done. In FIG. 11, the adjustment lever 35 that supports the main body support shaft 36 at the low position is indicated by a solid line, and the adjustment lever 35 that supports the main body support shaft 36 at the high position is indicated by a two-dot chain line. Further, a knob 35d is provided at the tip of the adjustment lever 35 so as to protrude on the opposite side to the protrusion 35c (see FIG. 9).

  Further, in the state where the main body support shaft 36 is supported at the low position and the state where the main body support shaft 36 is supported at the high position, the position of the main body support shaft 36 in the vertical direction changes, while the position in the front-rear direction is maintained. Specifically, the locking hole 33d and the locking hole 33e are provided on opposite sides of the rotation center C1, and when the main body support shaft 36 is supported at a low position, the center line of the main body support shaft 36 C2 is located below the rotation center C1. Therefore, when the adjustment lever 35 rotates 180 degrees and the protrusion 35c moves from the locking hole 33d to the locking hole 33e, the center line C2 is positioned above the rotation center C1, while the center line C2 is positioned in the front-rear direction. Is maintained.

  The adjustment mechanism for adjusting the height of the main body support shaft 36 is not limited to this. For example, the heat sink arm 31 is provided with a member that can move up and down relatively with respect to the upper edge portions 32L and 32R. A member may hold the main body support shaft 36.

  As described above, the heat sink assembly 1 is provided with the heat sink support shaft 25 that supports the heat sink 30 so as to be opened and closed. As shown in FIG. 4, the support plate 23 has a triangular shape in a side view of the heat sink assembly 1. The rear portion of the support plate 23 extends obliquely upward from the base body 21, and the rear end 23 b of the support plate 23 supports the heat sink support shaft 25 at a position away from the base body 21. The supported hole 45 e provided in the heat sink body 40 and the main body support shaft 36 fitted in the supported hole 45 e are located in the extending direction of the heat sink arm 31 with respect to the heat sink support shaft 25. That is, when the heat sink 30 is closed, the supported holes 45e and the main body support shaft 36 are substantially equal in height to the heat sink support shaft 25, and the supported holes 45e and the main body support shaft 36 are located on the heat sink support shaft 25. It is located in the front (direction indicated by Df).

  As a result, the distance between the heat sink support shaft 25 and the supported hole 45e is smaller than when the heat sink support shaft 25 is supported at a position lower than the supported hole 45e and the main body support shaft 36. As a result, when the lower surface 42a of the heat sink body 40 approaches the surface of the integrated circuit 201, the position of the lower surface 42a is suppressed from moving in the front-rear direction. FIG. 12 is a diagram for explaining the movement of the lower surface 42 a when the lower surface 42 a of the heat sink body 40 approaches the integrated circuit 201.

  In the figure, C3 indicates the position of the center of the heat sink support shaft 25, C2 indicates the position of the center of the main body support shaft 36, and they are separated by a distance R3. C4 indicates the position of the center of the heat sink support shaft 25 'to be compared, and the center C4 is provided at a position that is greatly separated from the center C3. The center C4 and the center C2 of the main body support shaft 36 are separated by a distance R4, and the distance R4 is larger than the distance R3.

As shown in the figure, the heat sink arm 31 is rotated around the heat sink supporting shaft 25, down to the center C2 is a height H of the main body support shaft 36, when arriving at the position indicated by C2 _3, with it, the body The center C2 of the support shaft 36 moves forward by a distance X3, and the lower surface 42a of the heat sink body 40 arrives at the integrated circuit 201. Similarly, the heat sink arm 31 is rotated around the heat sink supporting shaft 25 ', down to the center C2 is a height H of the main body support shaft 36, when arriving at the position indicated by C2 _4, with it, the main body support shaft 36 The center C2 moves forward by a distance X4. At this time, since the distance R4 is larger than the distance R3, the forward moving distance X4 is also larger than the distance X3, and the forward moving distance of the lower surface 42a is also the case where the heat sink arm 31 rotates about the heat sink support shaft 25. Compared to

  Thus, the heat sink support shaft 25 is supported at a position away from the base main body 21 and the distance R3 between the heat sink support shaft 25 and the main body support shaft 36 is reduced, so that the main body support shaft 36 moves forward. As a result, the forward movement of the lower surface 42a of the heat sink body 40 is also suppressed.

  Such forward movement of the lower surface 42a also occurs when the heat sink 30 is pushed down by the cams 12L and 12R after the lower surface 42a reaches the surface of the integrated circuit 201. That is, when the cams 12L and 12R push down the upper edge portions 32L and 32R, the height of the lower surface 42a, that is, the height of the fin assembly 41 is not changed, and the compression spring 46 contracts to support the fin cover 45 and the main body. Only the position of the shaft 36 is lowered. In this case, the fin cover 45 and the fin assembly 41 move forward together with the main body support shaft 36, and the lower surface 42 a is shifted forward relative to the surface of the integrated circuit 201. Therefore, by moving the distance R3 between the heat sink support shaft 25 and the main body support shaft 36, the forward movement of the lower surface 42a that occurs in such a case can be suppressed.

  In the heat sink assembly 1 described above, the pair of left and right cams 12L and 12R are arranged so as to face each other in the direction of the rotation axis at positions separated in the direction of the rotation axis, and the upper edges 32L and 32R of the heat sink 30 are connected to each other. It is provided so that it can be pressed. Thereby, it is possible to suppress the bias of the force acting on the integrated circuit 201 from the lower surface 42a of the heat sink 30. That is, the force acting on the right side of the integrated circuit 201 and the force acting on the left side can be balanced from the lower surface 42 a of the heat sink 30. Further, the common rotating shafts of the left and right cams 12L and 12R are made common like the common rotating shaft 11 in the heat sink assembly 1, and the lever for rotating the left and right cams 12L and 12R is made common like the integrated lever 14. The number of parts of the arm heat sink assembly can be reduced.

  The present invention is not limited to the heat sink assembly 1 described above, and various modifications can be made. For example, in the above description, the heat sink 30 is provided so as to be openable and closable with respect to the base member 20. However, the present invention may be applied to a heat sink assembly in which the heat sink is detachably provided from the base member.

  13 is a perspective view of the heat sink assembly 100 according to such a configuration, FIG. 14 is a perspective view of the heat sink assembly 100 with the cam mechanism 110 of the heat sink assembly 100 opened, and FIG. 15 is a view of the heat sink 130 being removed. 16 is a perspective view of the base member 120 and the cam mechanism 110, FIG. 16 is a rear view of the lower portion of the heat sink assembly 100, and FIG. 17 is a cross-sectional view taken along line XVII-XVII shown in FIG. In these drawings, the same portions as those described above are denoted by the same reference numerals, and the description thereof is omitted.

  As shown in FIG. 14, the heat sink assembly 100 includes a heat sink 130, a base member 120, a cam mechanism 110, and stopper arms 170L and 170R. The heat sink 130 can be detached from the base member 120 without the heat sink arm 31 and the heat sink support shaft 25 described above being provided (see FIG. 15).

  As shown in FIG. 15, the base member 120 includes a base body 21 and a support plate 123 attached to the side surface of the base body 21.

  Similar to the cam mechanism 10 described above, the cam mechanism 110 includes support arms 13L and 13R. As shown in FIG. 13, in the cam mechanism 110, the connection bar 113a is stretched over the support arms 13L and 13R, and the left and right support arms 13L and 13R and the connection bar 113a are integrally formed. The connecting bar 113a is formed so as to limit the rotation angle of the support arms 13L and 13R, similarly to the stopper 13c described above. That is, the connecting bar 113a is formed at a position where it contacts the support plate 123 when the support arms 13L, 13R rotate around the arm support shaft 24. In this example, a connecting bar 113a is stretched over the base end portions 13a of the support arms 13L and 13R.

  In the heat sink assembly 100, as shown in FIG. 13, when the support arms 13L and 13R are rotated upward, the cams 12L and 12R are located at the center of the upper right edge 45ar and the upper left edge 45al provided on the fin cover 45. The lengths of the support arms 13L and 13R are set so as to arrive above the portion. A base member 139 is disposed on the center of the left and right upper edge portions 45ar and 45al, and the cams 12L and 12R that have arrived above the upper edge portions 45ar and 45al pass through the left and right base member 139. Then, the center portion of the upper edge portions 45ar and 45al is pressed from above. The base member 139 is a plate-like member extending upward along the side surface of the fan base 62 (see FIG. 14), and the cams 12L and 12R press the upper surface of the base member 139 downward. As described above, the lower surface 42a is located below the center of the fin cover 45, and when the integrated lever 14 is operated and the cams 12L and 12R rotate together with the integrated lever 14, the pressing force of the cams 12L and 12R is reduced to the lower surface. Acts perpendicularly to 42a.

  The base member 139 is attached to the fin cover 45 by a stopper 138. Specifically, as shown in FIG. 17, a mounting portion 139 a extending downward on the inside of the fin cover 45 is provided at the lower portion of the base member 139. On the other hand, the stopper 138 is disposed outside the side surface portion 45 d of the fin cover 45. The stopper 138 is provided with a cylindrical portion 138a that fits into a through hole 45f formed in the side surface portion 45d. A screw hole 139b is formed in the attachment portion 139a at a position corresponding to the tube portion 138a, and the attachment portion 139a is attached by a bolt 137 fitted to the tube portion 138a. Further, a through hole 139c is formed in the base member 139 at a portion located above the upper right edge 45ar. On the other hand, the stopper 138 is provided with a protrusion 138b that fits into the through hole 139c. This restricts the movement of the base member 139 relative to the upper right edge 45ar. The base member 139 is also attached to the upper left edge 45al in the same manner as the upper right edge 45ar.

  The left and right stopper arms 170L and 170R regulate the separation of the common rotary shaft 11 from the base member 139 by the reaction force received by the cams 12L and 12R from the base member 139 when the cams 12L and 12R rotate on the base member 139. It is a member to do. In this example, as shown in FIG. 15, the stopper arms 170L and 170R are disposed on the opposite side of the support arms 13L and 13R with the base body 21 interposed therebetween. A stopper arm support shaft 171 supported by a support plate 123 is provided on the opposite side of the arm support shaft 24 across the base body 21. The base end portions 170a of the stopper arms 170L and 170R are rotatably supported by a stopper arm support shaft 171. The stopper arms 170L and 170R are rotatable about the stopper arm support shaft 171. A hook 170b is formed at the tip of the stopper arms 170L and 170R, and the hook 170b is caught by the common rotating shaft 11 located above the base member 139, thereby restricting the movement of the common rotating shaft 11. The

  The connecting bar 170c is also stretched over the left and right stopper arms 170L and 170R. The connecting bar 170c is also provided so as to limit the rotation angle of the stopper arms 170L and 170R. Specifically, as shown in FIG. 16, a contact portion 170d positioned below both ends of the connection bar 170c is formed in the middle of the connection bar 170c. The stopper arms 170L and 170R can be rotated in the direction in which the stopper arms 170L and 170R are opened until the contact portion 170d contacts the stopper arm support shaft 171.

It is a perspective view of a heat sink assembly which is an example of an embodiment of the present invention. It is a perspective view of the heat sink assembly of the state which removed the cooling fan main body. It is a perspective view of the said heat sink assembly of the state which opened the cam mechanism and heat sink which the said heat sink assembly has. It is a side view of the said heat sink assembly. It is a top view of the heat sink which the said heat sink assembly has. FIG. 4 is a side view of a cam and an integrated lever obtained when facing the VI direction shown in FIG. 3. It is a side view of the said heat sink. It is a figure which decomposes | disassembles and shows the said heat sink to an up-down direction. It is a figure which decomposes | disassembles and shows the said heat sink in the left-right direction. It is sectional drawing in the XX line shown in FIG. It is a side view of the heat sink arm for demonstrating the adjustment mechanism provided in the said heat sink assembly. It is a figure for demonstrating a motion of the said lower surface when the lower surface of the heat sink main body which a heat sink has approaches an integrated circuit. It is a perspective view of the heat sink assembly which concerns on the other form of this invention. FIG. 14 is a perspective view of the heat sink assembly in a state where a cam mechanism included in the heat sink assembly shown in FIG. 13 is opened. FIG. 14 is a perspective view of the base member and the cam mechanism in a state where a heat sink included in the heat sink assembly shown in FIG. 13 is removed. FIG. 14 is a rear view of the lower part of the heat sink assembly shown in FIG. 13. It is sectional drawing of the XVII-XVII line shown in FIG.

Explanation of symbols

  1,100 heat sink assembly, 10,110 cam mechanism, 11 common rotating shaft, 12L, 12R cam, 12b pressing surface, 12c slide surface, 12d protrusion, 13L, 13R support arm, 14 integral lever, 14L, 14R lever arm portion, 14c Connecting bar, 20, 120 Base member, 21 Base body, 23, 123 Support plate, 24 Arm support shaft, 25 Heat sink support shaft, 30, 130 Heat sink, 31 Heat sink arm, 32L, 32R Left and right upper edges, 33L, 33R Side surface, 35 Adjustment lever, 36 Main body support shaft, 39 Pressed plate, 40 Heat sink main body, 41 Fin assembly, 41a Fin, 42 Lower base, 42a Lower surface, 43 Upper base, 45 Fin cover, 45ar Upper right edge, 4 al Upper left edge, 45e Supported hole (supported part), 46 Compression spring, 47 Bolt, 60 Fan, 61 Fan body, 62 Fan base, 139 Base member, 170L, 170R Stopper arm, 200 Circuit board, 201 Integrated circuit , C1 rotation center of the adjustment lever, C2 center of the body support shaft, C3 center of the heat sink support shaft.

Claims (12)

A lower surface capable of contacting an integrated circuit mounted on the substrate; and left and right upper edges positioned above the lower surface, the lower surface being positioned below the left and right upper edges. A heat sink provided;
A pair of left and right cams that rotate and press the heat sink from above, arranged to face the rotation axis direction at positions away from the rotation axis direction, and capable of pressing the upper edge portions;
One or a plurality of levers for rotating the pair of left and right cams;
A base member that can be disposed on the substrate;
One or a plurality of arms extending from the base member and rotatably supporting the rotation shafts of the pair of left and right cams;
A heat sink assembly comprising: The heat sink assembly of claim 1,
A support shaft supported by the base member;
The one or more arms are provided rotatably about the support shaft,
The pair of left and right cams are provided so as to be movable in a direction approaching or leaving the left and right upper edges by rotation of the one or more arms.
A heat sink assembly characterized by that. The heat sink assembly of claim 1,
The one or more levers are attached to each of the pair of left and right cams, and have an integral lever that integrally rotates the pair of left and right cams,
A heat sink assembly characterized by that. The heat sink assembly of claim 3,
A cooling fan between the left and right upper edges;
The integrated lever has a pair of lever arm portions attached to the pair of left and right cams, and a connecting portion for connecting the pair of lever arm portions,
In a state where the pair of left and right cams rotate with the integrated lever and press the heat sink, the pair of lever arm portions and the connecting portion extend along the side surface of the cooling fan.
A heat sink assembly characterized by that. The heat sink assembly of claim 1,
As the rotation shaft of the pair of left and right cams, a common rotation shaft spanned between the pair of left and right cams,
A heat sink assembly characterized by that. The heat sink assembly of claim 1,
The heat sink has a plurality of cooling fins above the lower surface,
As the one or more arms, it has a pair of left and right arms provided so that the plurality of cooling fins are positioned between them,
A heat sink assembly characterized by that. The heat sink assembly of claim 6 wherein:
The plurality of cooling fins are arranged side by side at intervals,
The pair of left and right arms are separated in the direction in which the plurality of cooling fins are arranged,
A heat sink assembly characterized by that. The heat sink assembly of claim 1,
The heat sink has an adjustment mechanism that adjusts the height of the left and right upper edge portions from the lower surface.
A heat sink assembly characterized by that. The heat sink assembly of claim 8,
The heat sink is
A heat sink body having the lower surface;
The heat sink main body is a separate member, and includes the left and right upper edge portions and a pair of side surface portions that are respectively suspended from the left and right upper edge portions and the heat sink main body is disposed therebetween. A heat sink arm,
The adjustment mechanism includes an adjustment lever attached to the pair of side surface parts so as to be rotatable with respect to the pair of side surface parts, and the adjustment lever supports the heat sink body by a position deviated from the rotation center. is doing,
A heat sink assembly characterized by that. The heat sink assembly of claim 1,
The heat sink is supported by a heat sink support shaft provided on the base member so as to be openable and closable with respect to the base member.
A heat sink assembly characterized by that. The heat sink assembly of claim 10,
The heat sink is
A heat sink arm supported by the heat sink support shaft and rotatable about the heat sink support shaft;
A heat sink body having the lower surface and a supported portion supported by the heat sink arm at the top,
The base member has a base body that can be disposed on the substrate, and a support portion that supports the heat sink support shaft,
The support portion supports the heat sink support shaft at a position away from the base body upward.
A heat sink assembly characterized by that. The heat sink assembly of claim 11, wherein
The heat sink arm is provided to extend from the heat sink support shaft;
The supported portion is located in the extending direction of the heat sink arm with respect to the heat sink support shaft,
A heat sink assembly characterized by that.

Images