JP4269690B2 - Heat dissipation device - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to a heat dissipation device including a fan, a radiator, and a shroud, and relates to mounting the radiator to a shroud.
[0002]
[Prior art]
In the heat dissipating device described in Patent Literature 1, the radiator is fixed to the shroud with a bolt or the like in a bracket provided on the radiator. Further, the cooler condenser is fixed to the shroud by being fixed to a bracket provided on the radiator with a bolt or the like.
[0003]
[Patent Document 1]
JP-A-6-286657
[0004]
[Problems to be Solved by the Invention, Means for Solving Problems, and Effects]
However, in the heat dissipating device described in Patent Document 1, many parts such as bolts are required when fixing the radiator and the cooler condenser to the shroud. This invention makes it a subject to reduce the number of parts required when fixing a heat radiator to a shroud. This problem is solved by making the heat dissipation device have the configuration of each aspect described below. As with the claims, each aspect is divided into sections, each section is numbered, and is described in a form that cites the numbers of other sections as necessary. This is merely for the purpose of facilitating understanding of the technology described in this specification, and the technical features described in this specification and combinations thereof should not be interpreted as being limited to the following items. Absent. In addition, when a plurality of items are described in one section, it is not always necessary to employ all items together, and it is also possible to take out only some items and employ them.
[0005]
  Of the following items,(twenty one) The term corresponds to claim 1, (twenty three) Term ~ (twenty five) The terms correspond to claims 2 to 4, respectively.
[0006]
(1) A heat dissipation device including a fan, a radiator and a shroud, wherein the fan and radiator are held by the shroud,
A fan holding portion provided on the shroud to hold the fan;
Including a fitting protrusion provided on one of the outer peripheral part of the radiator and the inner peripheral part of the shroud opposed to the outer peripheral part, and a fitting recess provided on the other, and fitting with the fitting protrusions A radiator fixing portion that prevents relative movement in the axial direction with respect to the shroud of the radiator by fitting with the recess; and
A heat dissipation device comprising:
In the heat dissipation device described in this section, a fitting protrusion is provided on one of the outer peripheral portion of the radiator and the inner peripheral portion of the shroud, and a fitting recess is provided on the other. The relative movement in the axial direction of the shroud of the radiator (which is the axial direction of the fan) is prevented by the fitting with the fitting recess.
As described above, in the heat dissipation device described in this section, since the radiator is fixed by fitting the fitting protrusion and the fitting recess, a fixing bolt or the like is unnecessary, and is necessary for fixing. The number of parts can be reduced. In addition, the work time required for fixing can be shortened.
(2) The fan holding portion is provided on a front plate of the shroud,
By utilizing the elastic deformation that protrudes outwardly of at least one of the pair of side walls facing each other of the shroud, the fitting protrusion and the fitting recess are fitted, whereby the radiator The heat dissipation device according to item (1), which is fixed to the shroud.
In the heat dissipation device described in this section, the radiator is fitted and fixed to the shroud in the axial direction. In this case, the shroud side wall is elastically deformed in a direction that protrudes outwardly, Thus, the fitting protrusion and the fitting recess are fitted. The side wall to be elastically deformed may be either one or both of a pair of two side walls.
It is also possible to allow the fitting protrusion and the fitting recess to be fitted by elastically deforming at least one of the pair of side walls in a direction away from the other side wall. It is an embodiment of the present invention. However, in that case, if the side wall is easily elastically deformed in order to facilitate the fitting between the fitting protrusion and the fitting recess, the force applied to the side wall from the radiator in use (for example, The side walls are also elastic due to static load, dynamic load caused by vibration of the heat dissipation device, wind force against the heatsink, centrifugal force acting on the heatsink when the heatsink is mounted on the vehicle, etc. It becomes easy to deform | transform and it becomes easy to remove | fitting the fitting protrusion and the fitting recessed part. On the other hand, when the fitting protrusion and the fitting recess are fitted by elastic deformation that protrudes outward from the side wall, the central part is outwardly placed at the central part in the longitudinal direction of the side wall. If the pushing force is applied, the center portion of the side wall and the portion adjacent thereto can be easily separated from the other side wall and the fitting protrusion and the fitting recess can be fitted. On the other hand, if the force applied to the side wall from the radiator is received by both ends of the side wall, the elastic deformation of the side wall due to the force can be kept small, and the fitting protrusion and the fitting recess are fitted. Can be prevented from coming off easily.
(3) In the item (1) or (2), the shroud has a pair of side walls opposed to each other in the vertical direction, and the radiator is fixed between the pair of side walls opposed in the vertical direction. The heat dissipation device described.
The radiator may be fixed between the side walls facing each other in the vertical direction or may be fixed between the corresponding side walls in the horizontal direction, but it is preferable that the radiator is fixed between the side walls facing each other in the vertical direction. There are many. One of the reasons for this is that the radiator is often more horizontally long than if it is vertically long, inevitably the side walls facing each other in the vertical direction are longer than the side walls facing each other in the horizontal direction, It is easy to increase the amount of elastic deformation, and it is often easy to fit the fitting projection and the fitting recess. Of the side walls facing each other in the vertical direction, the lower side wall is often made relatively thick in order to support the weight of the radiator (when the heat dissipation device is mounted in the engine room of a vehicle, The side walls on both the upper and lower sides are often made relatively thick in order to resist the dynamic load in the vertical direction caused by bounce and rebound.) One. The vertical direction and the horizontal direction are directions orthogonal to the axial direction. When the heat dissipation device is mounted in the engine room of the vehicle, the axial direction corresponds to the longitudinal direction of the vehicle, and the horizontal direction corresponds to the width direction of the vehicle. In many cases, it is in a corresponding state.
(4) The shroud includes a front plate, two side walls facing each other in the vertical direction, and two side walls facing each other in the lateral direction,
The radiator is held between two side walls facing in the vertical direction, and the two side walls facing in the lateral direction increase the distance between the ends of the two side walls facing in the vertical direction. The heat dissipation device according to any one of items (1) to (3), wherein elastic deformation is suppressed.
In the heat radiating device described in this section, the shroud has a box-shaped portion that is generally box-shaped. The box-shaped part is constituted by a front plate and two pairs of side walls facing each other.
The two side walls opposed in the vertical direction are side walls extending in the horizontal direction, and the two side walls opposed in the horizontal direction are side walls extending in the vertical direction. According to the side wall extending in the vertical direction, deformation in which the distance between the end portions of the two side walls extending in the horizontal direction is suppressed is suppressed.
[0007]
(5) Any of (1) to (4), wherein the shroud includes a deformation suppressing portion that suppresses elastic deformation in which a distance between both end portions in the longitudinal direction of the two side walls to which the radiator is fixed is increased. The heat radiating device as described in one.
The deformation suppressing portion suppresses elastic deformation in which the distance between both end portions in the longitudinal direction of the two side walls to which the radiator is fixed is widened.
When the shroud has a pair of side walls opposed in the vertical direction and a pair of side walls opposed in the lateral direction as described in the above item (4), the shroud is opposed in the vertical direction by the pair of side walls opposed in the horizontal direction. The elastic deformation in which the distance between both end portions in the longitudinal direction of the pair of side walls is increased is suppressed, and the same elastic deformation of the pair of side walls facing in the lateral direction is suppressed by the pair of side walls facing in the vertical direction.
It is also possible to suppress the above-described elastic deformation by providing stays that connect both end portions of the two side walls holding the radiator and the front plate.
On the other hand, by providing the deformation suppressing portion, when a force is applied to the intermediate portion of the side wall, the side wall is elastically deformed in a direction that protrudes outward. In this sense, the deformation suppressing unit can be referred to as a deformation defining unit.
(6) The shroud has a pair of side walls opposed to each other in the vertical direction, the radiator is fixed between the pair of side walls, and the deformation is made near both ends in the longitudinal direction of the pair of side walls. The heat radiating device according to (5), wherein the heat radiating device includes a support device provided with a suppressing portion, and the heat radiating device is provided near both ends in the longitudinal direction of the pair of side walls or outside the both end portions.
When the heat dissipating device is mounted in the engine room of the vehicle, the heat dissipating device is fixed to the vehicle body in the vicinity of the both ends in the longitudinal direction of the side wall extending in the lateral direction that holds the radiator of the shroud or outside the both ends. Thereby, the dynamic load caused by the static load of the radiator and the bouncing / rebounding of the vehicle body is substantially received by both end portions of the side wall, and transmitted to the support device via the deformation suppressing portion. The shroud only needs to intensively increase the strength and rigidity of the portion that hits this force transmission path, and it is easy to reduce the weight as a whole.
[0008]
(7) Any one of the items (2) to (6), wherein each of the two side walls to which the radiator is fixed is provided with one or more of the fitting recess and the fitting protrusion. The heat radiating device as described in one.
In the heat radiating device described in this section, at least one of the fitting protrusion and the fitting recess is provided on one side wall.
One side wall may be provided with one or two or more of the fitting protrusions and the fitting recesses. For example, in the case of one, it is provided at a substantially central portion in the longitudinal direction of the side wall, and in the case of two or more, it is provided with a gap in the longitudinal direction of the side wall or with a gap in the axial direction. can do.
Further, the number of either one of the fitting protrusion and the fitting recess provided on each of the two side walls may be the same or different. For example, the same number can be provided on both side walls, one can be provided on one side wall, and two or more can be provided on the other side wall.
In addition, in the relationship between one radiator and a shroud, the fitting protrusion and the fitting recess correspond one-to-one. However, as described in [Embodiment of the invention] When the radiator is fixed, either one of the fitting protrusion and the fitting recess provided on the shroud and the other two provided on each of the two radiators of the plurality of radiators It may be fitted.
(8) At least one of the fitting recess and the fitting protrusion is provided on at least one of the two side walls facing each other, and at least two positions of the one side wall are respectively The heat dissipating device according to any one of (2) to (7), wherein the heat dissipating device is positioned on the end side from the center in the longitudinal direction.
When the heat sink is fixed between a pair of opposite side walls and a deformation suppressing portion is provided to suppress elastic deformation in which the distance between both end portions in the longitudinal direction of the side walls is widened, When a force is applied to the central portion or two adjacent portions), the elastic deformation amount (deflection amount) at the central portion in the longitudinal direction of the side wall is the largest, and the elastic deformation amounts at both ends are the smallest. Therefore, if either one of the fitting recess and the fitting protrusion is provided at a position close to the central portion in the longitudinal direction of the side wall, the fitting protrusion and the fitting recess are fitted when the radiator is fixed. If it is provided in the vicinity of both ends in the longitudinal direction, the fitting becomes difficult.
When the fitting protrusion and the fitting recess are fitted using the elastic deformation of the side wall, it is usually easy to remove the fitting if fitting is easy. This is not necessarily the case when the position where the force is applied for elastic deformation and the position where the force is applied to the side wall in the usage state are different. In the state of use, force is applied to the side wall by the weight and inertial force of the radiator, but the position where they are applied can be at both ends in the longitudinal direction of the side wall. Even when a force is applied, the side wall is not easily elastically deformed, and the fitting protrusion and the fitting recess are not easily fitted. On the other hand, when assembling the radiator to the shroud, if a force is applied to the middle part of the side wall in the longitudinal direction, the side wall can be easily elastically deformed, and the fitting protrusion and the fitting recess can be fitted deeply. It can be done.
Considering that it is inevitable that a certain amount of dimensional error will occur in the heatsink and shroud, and that the fitting protrusion and fitting recess should not be disengaged even if there is a dimensional error. It is desirable that the amount of fitting (the depth of fitting) between the fitting protrusion and the fitting recess be a certain amount or more. From this point of view, it is desirable that the fitting protrusion and the fitting recess be provided in a portion where a relatively large amount of elastic deformation can be obtained by applying a force to the middle portion of the side wall. It is desirable to set “one of the positions of the concave portion” to a position closer to the center by 1/6 or more of the length in the longitudinal direction from both ends in the longitudinal direction of the side wall, 1/4, 3/10, 2/6. , More preferably 3/8 or more, and a position closer to the center.
However, when it is necessary to prevent relative rotation of the radiator with respect to the shroud (rotation about a straight line orthogonal to the axial direction of the heat dissipation device) by fitting two or more fitting protrusions and fitting recesses. For this, it is advantageous that the distance between the two or more pairs of the fitting protrusions and the fitting recesses is large, and it is desirable to provide them in the vicinity of both ends in the longitudinal direction of the side wall. “The position of either one of the fitting protrusion and the fitting recess” is desirably set in consideration of the number of the fitting protrusions and the fitting recess provided, and these circumstances.
Note that the “use state of the heat radiating device” is not during the production of the heat radiating device (when the radiator is fixed to the shroud) or during the mounting operation of the heat radiating device (when the heat radiating device is being attached to the main body) Is a state in which the heat dissipation device is operated in a state where the original function is exhibited, or a device (including a vehicle) to which the heat dissipation device is attached is operated (the main switch of the device main body is ON) In this state, the heat dissipation device is not always in operation).
(9) At least one position defining portion that defines the position of the radiator in the axial direction is provided on at least one of the two side walls to which the radiator is fixed. The heat dissipation apparatus as described in any one.
If the position fixing portion defines the axial fixing position of the radiator with respect to the shroud, the relative position between the fitting protrusion and the fitting recess is determined, and the fixing operation of the radiator is facilitated. It is also possible to provide the position defining portion by projecting from a portion other than the side wall, for example, the front plate. However, since the side wall is formed so as to extend in a direction away from the front plate, it is often easier to provide the position defining portion on the side wall. In addition, not only the positioning in the axial direction but also a position defining part that defines the position in the lateral direction can be provided. The pair of side walls opposed to each other in the lateral direction can also be used as the lateral position defining portion.
[0009]
(10) The side wall has a step portion in which a distance between the opposing side walls is larger in a portion farther than a portion close to the front plate. Heat dissipation device.
If the side wall has a shape having a step portion, the rigidity of the side wall can be increased as compared with a case where the side wall is not provided.
Further, if the portion farther than the portion close to the front plate has a shape in which the dimension between the side walls is larger, the die can be easily removed when manufacturing the shroud.
Furthermore, the step portion can be used as a position defining portion that defines the movement limit in the axial direction of the radiator.
In addition, if the side wall is formed with a flat part with a constant interval between the side walls and a step part with a change in the interval, and a plurality of flat parts are formed and a plurality of radiators are fixed to them, they are fixed. There is an advantage that the work becomes easy. Each radiator is fitted from the opening side opposite to the front plate, and it is fitted from the larger inner dimension, so it is easier to fit the radiator compared to when there is no step part. It becomes. Moreover, since the amount of elastic deformation increases as the flat portion farther from the front plate among the plurality of flat portions, fixing the radiator in order from the flat portion closer to the front plate, when fixing the subsequent radiator It is possible to satisfactorily avoid the disconnection between the fitting protrusion and the fitting recess of the radiator that has been previously fixed.
[0010]
(11) The heat dissipation device according to any one of (1) to (10), wherein a fitting protrusion is provided in the radiator and a fitting recess is provided in the shroud.
(12) The heat radiation apparatus according to item (11), wherein a generally groove-shaped attachment member is provided on an outer peripheral portion of the radiator, and the attachment member has the fitting protrusion.
The groove-shaped attachment member includes a pair of side wall portions and a connecting portion that connects the side wall portions, and has a U-shaped cross section. This attachment member may be fixed to the outer peripheral surface of the radiator at the connecting portion, and fixed to the outer peripheral portion of the radiator at the free end portion that is the end portion opposite to the connecting portion side of the pair of side wall portions. Also good. In the former case, the fitting protrusion is projected from the edge of at least one free end side of the pair of side wall portions, and in the latter case, at least one connecting portion side (base) of the pair of side wall portions. It protrudes from the end edge or the connecting portion. When fitting protrusions are projected from both of the pair of side wall portions, the outer peripheral portion of the radiator is separated in the thickness direction of the radiator body, that is, the shaft when the radiator is fixed to the shroud. At least two fitting protrusions are provided in a state separated from each other in the direction.
Moreover, when a heat radiator is hold | maintained at a shroud via an attachment member, the end surface or connection part of the free end side of a pair of side wall will contact | abut to the inner peripheral surface of a shroud. From the viewpoint of ease of processing, it is desirable to provide a fitting protrusion on the free end side of the side wall, and from the viewpoint of widening the contact area with the shroud, it is desirable to provide a fitting protrusion on the connecting part side. . Even when the fitting protrusion is provided on the end surface on the free end side of the pair of side walls, a portion other than the fitting protrusion on the side wall is bent at a right angle with respect to the side wall to form a flange portion. By making contact with the inner peripheral surface of the shroud, the contact area between the mounting member and the shroud can be increased.
In the heat dissipation device of this section, even when the mounting member and the inner peripheral surface of the shroud are designed to contact each other over substantially the entire length of the mounting member, if the deformation suppressing portion is provided on the shroud, The force applied to the shroud from the mounting member causes the shroud side wall to elastically deform in an outwardly convex state, and if the deformation occurs slightly, the shroud side wall is no longer in the longitudinal center of the shroud. Will not touch. That is, the force applied to the side wall of the shroud through the mounting member from the radiator is substantially received by both ends in the longitudinal direction of the side wall of the shroud. In other words, both ends in the longitudinal direction of the mounting member function as force transmission portions to the shroud. Although the above has described the case where the mounting member is provided, even when the mounting member is not provided in the radiator, the force transmission portion from the radiator to the shroud is the both ends of the radiator in the longitudinal direction of the shroud side wall. It is the same as long as it is provided in the portion corresponding to.
(13) The mounting member includes a pair of side wall portions and a connecting portion that connects the side wall portions, and has a U-shaped cross-sectional shape, and an end surface of the pair of side walls is an inner peripheral surface of the shroud. The heat dissipating device according to the item (12), in which a fitting protrusion further contacting from the end face is fitted into a fitting recess in the side wall of the shroud.
[0011]
(14) The heat dissipating device includes a plurality of heat radiators, the shroud side wall includes a plurality of the step portions, and each of the plurality of heat dissipators is positioned at different step portions of the plurality of step portions. The heat radiating device according to any one of (10) to (13), which is fixed by
(15) Each of the plurality of radiators has an attachment member fixed to an outer peripheral portion thereof and abutting against an inner surface of a side wall of the shroud, and each of the attachment members of the plurality of radiators is the radiator itself. The heat radiating device according to item (14), wherein the heat dissipation device has a shape and a dimension determined based on at least one of the structure and the shape of the pair of side walls of the shroud.
The radiator is fixed by fitting the fitting protrusion and the fitting recess with the mounting member in contact with the inner surface of the side wall of the shroud, but the side wall has a stepped shape. The plurality of radiators are fixed while being positioned by different step portions.
For example, if the dimensions of two radiators in the opposing direction of the pair of side walls of the shroud to which they are to be fixed are substantially the same, the radiator located on the front plate side of the shroud and the opening side of the shroud With the radiator, the dimension of the mounting member in the above direction is larger for the radiator located on the opening side of the shroud.
Moreover, the position of the action part is not necessarily the same for each of the two radiators. For example, when an action part is located in the upper part of a radiator, it may be located in a center part. In this case, the dimension of the mounting member provided on the lower side of the radiator whose action part is located on the upper side is reduced, and that of the mounting member provided on the lower side of the radiator located on the central part is reduced. If it enlarges, the area of the part which action parts will overlap can be enlarged. Moreover, the lower end of each action part can also be made to become substantially the same height as the duct surface of a shroud.
As described above, (i) the shape and size of each of the mounting members of the plurality of radiators are the circumstances of the radiator itself, such as the size of each radiator, the position of the action part with respect to the entirety of each radiator, and (ii) the heat dissipation. It can be determined on the basis of the circumstances related to the shroud, such as the distance between the side walls of the shroud to which each container is fixed, the position and shape of either the fitting recess or the fitting protrusion. The shape of the two attachment members provided in the radiator may not be the same.
[0012]
(16) One of the two radiators fixed to the shroud is a radiator that cools the engine of the vehicle, and the other is a cooler condenser that holds a refrigerant of an air conditioner that adjusts the temperature in the vehicle interior. The heat radiating device according to item (14) or (15).
(17) In the item (16), the radiator and the cooler condenser are fixed in a state where the area of the portion where the action portions overlap is maximized, and one end surfaces of the action portions coincide with the duct surface of the shroud. The heat dissipation device described.
If the radiator and the cooler condenser are fixed in such a manner that the area of the overlapping portions of the working portions is maximized and one end surface of the working portion is the same as the duct surface, a large heat radiation effect can be obtained.
[0013]
(18) The heat radiating device according to any one of (1) to (17), wherein the shroud is manufactured by injection molding.
When the side surface of the shroud has a step portion in which the inner dimension is larger on the opening side than the portion close to the front plate, the die can be easily removed, and the number of slide members can be reduced. The shroud can be made of resin.
[0014]
(19) A heat dissipation device including a fan, a radiator and a shroud,
  The fan is held on the front plate of the shroud;
  The radiator extends from the front plate in a direction intersecting the front plate and is held by two side walls facing each other, and a portion where the distance between the side walls is far from the portion near the front plate is larger. The heat dissipation device is characterized in that an approach limit of the radiator to the front plate is defined by contact of the radiator with the step.
  The technical features described in any one of the items (1) to (18) can be adopted for the heat dissipation device described in this item.
(20) A mounting member having a U-shaped cross-sectional shape provided with a pair of side wall portions and a connecting portion for connecting the side wall portions is provided on the outer peripheral portion of the radiator. The heat radiation device according to item (19), wherein the fitting protrusion provided on one of the two and the fitting protrusion provided on the other have different lengths.
  In the heat dissipation device described in this section, the radiator is provided with a fitting projection, and the shroud is provided with a fitting recess. Since the side wall of the shroud has a stepped portion, as described in [Embodiment of the invention], if the length of a pair of fitting projections separated in the axial direction is changed, each fitting projection is changed. The fitting amount of the part and the fitting recess provided in the shroud can be made the same.
(21) A heat dissipation device including a fan, two radiators and a shroud, wherein the fan and two radiators are held by the shroud,
  The fan is held on the front plate of the shroud;
  The shroud includes two side walls extending from the front plate in a direction intersecting with the front plate and facing each other, and the two side walls are located farther from the portion closer to the front plate. Has a plurality of stepped portions,
  The two radiators are respectively positioned at different step portions between the opposing side walls, and the action portions of the radiators are held in a substantially overlapping state when viewed from the axial direction. Heat dissipation device.
  The technical features described in any one of the items (1) to (20) can be employed in the heat dissipation device described in this section.
(22) A fan holding portion is provided on the front plate, and a pair of side walls facing each other has a step portion in which the distance between these two side walls is larger in a portion farther from the portion closer to the front plate, and two side walls. A shroud comprising a radiator fixing part in at least one of the above.
  The technical features described in any one of the items (1) to (20) can be employed in the heat dissipation device described in this section.
(23) The two radiators are held by the shroud in a state where the area of the portion where the action portions overlap is maximized. (twenty one) Term or (twenty two) The heat radiating device according to the item.
(24) The heat dissipating device includes a fitting protrusion provided on one of each of the outer peripheral portions of the two radiators and each of the two opposite side walls of the shroud corresponding thereto, and the other A radiator fixing portion that prevents relative movement in the axial direction of each of the two radiators with respect to the shroud by fitting between the fitting protrusion and the fitting recess. Include (twenty one) Term or (twenty three) The heat radiating device according to any one of the items.
(25) By using the elastic deformation that protrudes outwardly of at least one of the pair of side walls facing each other of the shroud, the fitting protrusion and the fitting recess are fitted, Two radiators are each fixed to the shroud (twenty four) The heat radiating device according to the item.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
A heat radiating device according to an embodiment of the present invention will be described in detail with reference to the drawings.
As shown in FIG. 1, the heat dissipation device includes a radiator 10 as a heat radiator, a cooler condenser 12, a fan 14, and a shroud 16. The radiator 10, the cooler condenser 12 and the fan 14 are attached to the shroud 16.
In the present embodiment, the heat dissipation device is used in a vehicle and is mounted in an engine room. The radiator 10 cools the engine, and the cooler condenser 12 holds a refrigerant of an air conditioner that adjusts the temperature in the passenger compartment. The fan 14 supplies air cooled by the radiator 10 or the like to the engine.
[0016]
As shown in FIG. 1, the shroud 16 has a box-shaped portion 18 having a generally box shape. In FIG. 1, the shape of the shroud 16 is simplified, and only the portions necessary for the present invention are extracted and shown. The shroud 16 is often provided with a side panel or the like adjacent to the box-shaped portion 18.
The shroud 16 includes a front plate 20, a pair of side walls 24 and 26 that face each other in the vertical direction, and a pair of side walls 28 and 30 that face each other in the horizontal direction, thereby forming the box-shaped portion 18. In the present embodiment, the axial direction of the fan 14 held by the shroud 16 corresponds to the longitudinal direction of the vehicle. The vertical direction of the box-shaped portion 18 corresponds to the vertical direction of the vehicle, and the horizontal direction corresponds to the width direction of the vehicle. The axial direction, the vertical direction, and the horizontal direction are orthogonal to each other.
[0017]
The shroud 16 is fixed to a vehicle body (not shown) at a fixing portion 32 (only one is shown in the figure). The fixing portion 32 is provided near the corner of the box-shaped portion 18, that is, near both end portions of the side walls 24 and 26. During traveling of the vehicle, a load accompanying vibration in the vertical direction is applied in the longitudinal direction of the side walls 28 and 30, and the deformation of the side walls 24 and 26 is suppressed.
The fan 14 is held by a fan holding portion 33 provided on the front plate 20 of the shroud 16 via a fan motor.
As shown in FIGS. 2 and 3, the side walls 24, 26 have a stepped shape including a plurality of step portions 34, 35, 36 and flat portions 37, 38. The distance K between the side walls 24 and 26 (see FIG. 1) is reduced.
The step portions 34, 35 and 36 are portions where the distance K between the pair of side walls 24 and 26 changes, and the flat portions 37 and 38 are portions where the distance K is constant.
[0018]
The radiator 10 and the cooler condenser 12 are fixed between the side walls 24 and 26 facing in the vertical direction in a state where the radiator 10 is positioned on the front plate 20 side in the axial direction from the cooler condenser 12.
In the present embodiment, the shroud 16 is provided with a fitting recess, and the radiator 10 and the cooler condenser 12 are provided with a fitting protrusion.
Four fitting recesses are provided in each of the side walls 24 and 26 at the same position in the axial direction and spaced apart in the longitudinal direction, and at the same position in the longitudinal direction (the same position in the width direction) in the axial direction. Three are provided at intervals. Each of the side walls 24 and 26 is provided with twelve fitting recesses.
[0019]
In FIG. 4, the position of the fitting recessed part provided in the same position of the axial direction is shown. The four fitting recesses 40, 41, 42, 43 are provided at equal intervals and in a state where the two fitting recesses 40, 41 at both ends are located in the vicinity of both ends in the longitudinal direction of the side walls 24, 26. . Accordingly, the two intermediate fitting recesses 42 and 43 are located at positions separated from the longitudinal center S of the side walls 24 and 26 by about 1/6 end side of the longitudinal length L on the end side, in other words, Then, it is provided at a position closer to the center of about (5/6 · L) from both ends.
Further, as shown in FIG. 3, three fitting recesses are provided at the same position in the longitudinal direction and spaced apart in the axial direction. The fitting recess 40a closest to the front plate is provided at a position adjacent to the step portion 34 of the flat portion 37, and the intermediate fitting recess 40b is provided at the step portion 35 (including a part of the flat portion 37). A fitting recess 40c farthest from the front plate 20 (most opening side) is provided in the step portion 36 (including a part of the flat portion 38). As will be described later, two fitting protrusions are fitted into the middle fitting recess 40b.
[0020]
On the other hand, generally groove-shaped mounting members 50 and 52 are respectively provided on the upper and lower outer peripheral surfaces of the radiator 10 and the cooler condenser 12. The attachment members 50 and 52 include a connecting portion and a pair of side walls, and have a U-shaped cross section. In the attachment member 50, the connecting portion 54 is fixed to the main body of the radiator 10, and the fitting protrusions 62 and 64 are arranged at four equal intervals on the pair of side walls 58 and 60, and are fitted into the fitting recesses 40, 41, 42, and 43. It is provided at the corresponding position. The same applies to the cooler condenser 12, and the attachment member 52 is fixed to the cooler condenser 12 at the connecting portion 66, and four fitting protrusions 72, 74 correspond to the fitting recesses on the pair of side walls 68, 70. Provided in position.
[0021]
In the radiator 10, end surfaces 80, 82 on the side of the free ends of the side walls 58, 60 of the mounting member 50 abut against the flat portion 37 of the shroud 16, and fitting protrusions 62, 64 further protruding from the end surfaces 80, 82 are fitted. The fitting recesses 40a, 41a, 42a, 43a and the fitting recesses 40b, 41b, 42b, 43b are fixed in a fitted state. In the cooler condenser 12, the end faces 84 and 86 of the side walls 68 and 70 of the mounting member 52 are in contact with the flat portion 38 of the shroud 16, and the fitting protrusions 72 and 74 further protruding from the end faces 84 and 86 are the fitting recesses 40b, 41b, 42b, 43b and the fitting recesses 40c, 41c, 42c, 43c are fixed in a fitted state.
[0022]
The shapes of the mounting members 50 and 52 are (i) matters relating to the structure of the radiator 10 and the cooler condenser 12 itself, for example, (a) the size of the radiator 10 and the cooler condenser 12, and (b) the radiator 10 and the cooler condenser 12. Position relative to the entire action part (ventilation part) (for example, the radiator 10 has a case where the tank is located on the left and right and a case where the tank is located above and below, thereby changing the position of the action part relative to the whole); (Ii) matters related to the shape of the shroud 16 to which the radiator 10 and the cooler condenser 12 are fixed, for example, (a) the side walls 24 and 26 at positions where the radiator 10 and the cooler condenser 12 are fixed. It is determined based on the distance between them, (b) the shape of the fitting recess, (c) the shape, position, etc. of the duct surface 90.
In the present embodiment, the mounting members 50 and 52 have the largest overlapping portions between the operating portions of the radiator 10 and the cooler condenser 12, and the lower end surfaces of these operating portions are substantially the same as the duct surface 90 of the shroud 16. To be determined.
[0023]
In the attachment members 50 and 52 of the radiator 10 and the cooler condenser 12, when these are fixed to the shroud 16, the fitting protrusions 62 and 72 positioned on the front plate 20 side are respectively fitted on the opening side. It is shorter than the mating protrusions 64 and 74. Thereby, for example, as shown in FIG. 2, the fitting amount between the fitting protrusions 62 and 72 and the fitting recess and the fitting amount between the fitting protrusions 64 and 74 and the fitting recess are substantially the same. Can be.
[0024]
Further, the length from the connecting portion 54 to the end faces 80 and 82 in the attachment member 50 of the radiator 10 is made shorter than the length from the connecting portion 66 to the end faces 84 and 86 in the attachment member 52 of the cooler capacitor 12. Since the vertical dimension of the radiator 10 and the cooler condenser 12 is substantially the same, the length of the leg of the mounting member is shortened in the radiator fixed to the side closer to the front plate 20 in the axial direction. In the present embodiment, the mounting member 50 of the radiator 10 has a shorter leg than the mounting member 52 of the cooler condenser 12.
Accordingly, the area of the overlapping portion between the operating portions of the radiator 10 and the cooler condenser 12 is maximized, and the lower end surface of the operating portion is flush with the duct surface 90 of the shroud 16.
[0025]
Next, the case where the radiator 10 and the cooler condenser 12 are fixed between the pair of side walls 24 and 26 of the shroud 16 will be described.
The radiator 10 is fitted in the axial direction from the opening side of the box-shaped portion 18 of the shroud 16. In this case, it is assumed that the shorter fitting protrusion 62 is positioned on the front plate side. The distance K is increased by elastically deforming at least one of the side walls 24 and 26 in a convex direction. Then, the radiator 10 is pushed in the axial direction until the side surface 92 on the front plate side of the mounting member 50 comes into contact with the step portion 34 of the shroud 16. Thereby, the fitting protrusion 62 and the fitting recesses 40a, 41a, 42a, and 43a are fitted, and the fitting protrusion 64 and the fitting recesses 40b, 41b, 42b, and 43b are fitted. The lateral position of the radiator 10 is determined by the side walls 28 and 30.
Next, the cooler condenser 12 is similarly attached. The position of the cooler condenser 12 in the axial direction is determined by the contact of the side surface 94 of the mounting member 52 with the step portion 35. In this case, the fitting projection 72 is fitted into the fitting recesses 40b, 41b, 42b, and 43b, and the fitting projection 74 is fitted into the fitting recesses 40c, 41c, 42c, and 43c. In addition, the flat portions 38 of the side walls 24 and 26 are elastically deformed during fitting, but even if the flat portions 38 are largely elastically deformed, the flat portions 37 are not elastically deformed so much. Disengagement of the radiator 10 is avoided. In the present embodiment, the two fitting protrusions 66 and 72 are fitted into the fitting recesses 40b, 41b, 42b, and 43b.
[0026]
As described above, in the present embodiment, the radiator 10 and the cooler condenser 12 are fixed to the shroud 16 by utilizing the elastic deformation of the side walls 24 and 26. Therefore, bolts or the like are not necessary, and the number of parts required for fixing can be reduced. In addition, the work time for fixing can be shortened.
Furthermore, although the shroud 16 is manufactured by injection molding, since the inner dimension of the shroud 16 decreases toward the front plate, the sliding portion of the molding die can be reduced, and the cost required for mold production is reduced. Can be cheaper.
The pair of side walls 28 and 30 in the horizontal direction suppresses elastic deformation in which the distance between both ends in the longitudinal direction of the pair of side walls 24 and 26 in the vertical direction is widened. Thereby, the radiator 10 and the cooler condenser 12 can be kept in a fixed state when the vehicle is in use.
Furthermore, since the overlapping part of the action part is maximized and the lower end surface of the action part is fixed to be flush with the duct surface 90 of the shroud 16, the heat radiation effect can be enhanced.
Further, since the fitting recesses 40b, 41b, 42b, 43b are common to the two fitting protrusions 64, 72, the number of fitting recesses provided in the shroud 16 can be reduced accordingly. In this state, the axial movement of the radiator 10 can be reliably prevented by the cooler condenser 12.
Furthermore, since the force received by the radiator 10 and the cooler condenser 12 is transmitted to the shroud 16 via the mounting members 50 and 52 and received by the side walls 28 and 30, elastic deformation of the side walls 24 and 26 can be suppressed. .
[0027]
As described above, in the present embodiment, the support device is configured by the fixing portion 32 and the like, and the radiator fixing portion is formed by the fitting protrusions 62, 64, 72, and 74, the fitting recesses 40, 41, 42, and 43, and the like. Is formed, and the side wall 28, 30 and the like constitute a deformation suppressing portion.
[0028]
In addition, the radiator 10 and the cooler capacitor | condenser 12 can also be attached by another method. For example, the main body of the radiator 10 is inclined so that the fitting protrusion 62 and the fitting recesses 40a, 41a, 42a, 43a face each other between the upper side wall 24 and the radiator 10, and the fitting protrusion 64 And the fitting recesses 40b, 41b, 42b, and 43b face each other. Thereafter, by deforming the flat portion 37 of the side wall 26 so as to project outward, the fitting recesses 40a, 41a, 42a, 43a and the fitting protrusion 62 are fitted on both the side walls 24, 26. Then, the fitting recesses 40b, 41b, 42b, 43b and the fitting protrusion 64 are fitted.
[0029]
Further, the longitudinal direction, the axial position, the number, and the like of the fitting recess are not limited to those in the above embodiment. For example, it may be 2 or 3 in the longitudinal direction, or 5 or more. Furthermore, it can also be two or four in the axial direction. In the above embodiment, the fitting recesses 40b, 41b, 42b, and 43b are common to the fitting protrusion of the radiator 10 and the fitting protrusion of the cooler condenser 12, but the fitting protrusions have a one-to-one relationship. A fitting recess can be provided so as to correspond to the above. In addition, it is not essential to provide two fitting protrusions at positions spaced apart in the axial direction. The number of fitting protrusions can be one in the axial direction with respect to one radiator, or three or more.
[0030]
Furthermore, the shape of the fitting protrusion and the fitting recess is not limited. For example, in the attachment members 50 and 52, the lengths of the fitting protrusions 62 and 64 and the lengths of the fitting protrusions 72 and 74 can be the same. Accordingly, the shape and the like of the fitting recess may be changed as appropriate. Moreover, the free end part of a pair of side wall of the attachment members 50 and 52 can be bent, and a flange part can also be formed. In this case, the flange portion comes into contact with the shroud 16. Furthermore, the shape of the attachment members 50 and 52 is not questioned.
Further, it is not essential that the side wall of the shroud 16 has a stepped shape. Further, it is not indispensable to fix both the radiator 10 and the cooler condenser 12 to the shroud 15, and the present invention can be applied to the case where only one of them is fixed.
Further, the radiator 10 and the cooler condenser 12 may be fixed between the side walls 28 and 30 opposed in the lateral direction of the shroud 16.
In addition to the aspects described in the above [Problems to be Solved by the Invention, Problem Solving Means and Effects], the present invention can be implemented in variously modified and improved forms based on the knowledge of those skilled in the art. it can.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of a heat dissipation device of the present invention.
FIG. 2 is a cross-sectional view illustrating a main part of the heat dissipation device.
FIG. 3 is a perspective view showing a main part of the heat dissipation device.
FIG. 4 is a plan view showing a part of a shroud of the heat dissipation device.
[Explanation of symbols]
10 radiators
12 cooler condenser
16 shroud
33 fan holder
24,26 side walls
28, 30 side walls
34, 35, 36 steps
50, 52 mounting members
62, 64, 72, 74 fitting protrusion
40, 41, 42, 43 fitting recess

Claims (4)

A heat dissipation device including a fan, two radiators and a shroud, wherein the fan and two radiators are held by the shroud,
The fan is held on the front plate of the shroud;
The shroud includes two side walls extending from the front plate in a direction intersecting with the front plate and facing each other, and the two side walls are located farther from the portion closer to the front plate. Has a plurality of stepped portions,
The two radiators are respectively positioned at different step portions between the opposing side walls, and the action portions of the radiators are held in a substantially overlapping state when viewed from the axial direction. Heat dissipation device.   The heat radiating device according to claim 1, wherein the two radiators are held by the shroud in a state in which an area of a portion where the acting portions overlap each other is maximized.   The heat dissipating device is provided on one side of each of the outer peripheral portions of the two heat radiators and the two side walls of the shroud corresponding to each other, and on the other side. And a radiator fixing portion that prevents relative movement in the axial direction of each of the two radiators with respect to the shroud by fitting between the fitting protrusion and the fitting recess. The heat radiating device according to 1 or 2.   By utilizing the elastic deformation that protrudes outwardly of at least one of the pair of opposite side walls of the shroud, the fitting protrusion and the fitting recess are fitted to each other, thereby the two heat dissipations The heat dissipating device according to claim 3, wherein each device is fixed to the shroud.

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