JP2018159280A - Spacer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a novel spacer that can suppress overcool of a cylinder bore wall in the vicinity of an introduction port of cooling water and reduce a pressure loss at the time when the cooling water is introduced from the introduction port.SOLUTION: A spacer 5 is formed in a cylinder block 1 to surround cylinder bores 2 and is arranged in a cooling water flow passage 3 in which an introduction port of cooling water 3b is provided on an outside inner wall surface 3f. A spacer body 6 comprises a first portion 61 including an introduction port opposite part 61a facing the introduction port of cooling water, and a second portion 62 connected to the first portion to be positioned at an upstream side in a cooling water flow direction a of the first portion. The first portion is formed such that at least the introduction port opposite part and a portion at an opening side of the cooling water flow passage from the introduction port opposite part are positioned closer to a cylinder bore side than a width-direction center b of the cooling water flow passage. The second portion is formed to be positioned at an opposite side to a cylinder bore side with respect to the width-direction center of the cooling water flow passage.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a spacer disposed in a cooling water passage formed in a cylinder block of an internal combustion engine so as to surround a cylinder bore.

  In the cooling water flow path of the internal combustion engine, a spacer for regulating the flow (flow rate, flow velocity, etc.) of the circulating cooling water is disposed (see, for example, Patent Document 1). The cooling water flow path is provided with a water inlet and a water outlet as cooling water flow ports, and the cooling water introduced from the water inlet cools the cylinder bore wall while flowing through the cooling water flow path, and maintains an appropriate temperature. It is configured to be led out from the water outlet. In Patent Document 1, by configuring the cooling water passage so that the spacer does not block the spacer, it is possible to prevent the spacer from being a flow resistance of the flow of water into the cooling water, and to the outside of the cylinder block. It is described that it is easy to pass water.

JP 2005-120945 A

  In Patent Document 1, as a configuration for preventing the spacer from blocking the water inlet, (1) a notch is provided in a portion facing the water inlet of the spacer, and (2) the spacer is passed from a portion with high water pressure. It is described that a passage for guiding cooling water to the water port is provided. By the way, in the case of the structure of (1), the notch is provided in the part facing the water flow hole of the spacer, so that the cooling water flowing between the spacer and the cylinder bore wall passes through the notch of the spacer and becomes the water flow hole. It becomes easy to flow in and the cylinder bore wall in the vicinity of the water passage is likely to be supercooled. In the case of the configuration (2), the passage is composed of a concave passage recessed in the thickness direction of the spacer. However, since the concave passage is narrow and refracted in the middle, the water flow resistance is large and the pressure loss is reduced. There is a concern that will increase.

  The present invention has been made in view of the above, and is capable of suppressing overcooling of the cylinder bore wall in the vicinity of the cooling water outlet and reducing pressure loss when the cooling water is discharged from the outlet. The object is to provide a simple spacer.

  A spacer according to the present invention is formed in a cooling water passage formed in a cylinder block of an internal combustion engine so as to surround a cylinder bore and provided with a cooling water outlet on an outer inner wall surface on the opposite side to the cylinder bore. And a spacer main body having a shape that can be arranged in the cooling water flow path, wherein the spacer main body includes a first outlet portion that includes a outlet outlet facing portion facing the outlet of the cooling water, and the first portion. And a second part connected to the first part so as to be located upstream of the cooling water flow direction in the cooling water flow path, the first part comprising at least the outlet opening facing part and the second part The portion on the opening side of the cooling water flow path from the outlet facing portion is formed to be located on the cylinder bore side from the center in the width direction of the cooling water flow path, and the second portion is formed in the width direction of the cooling water flow path During ~ Characterized in that it is formed so as to be positioned on the opposite side also cylinder bore side of the.

  According to the spacer according to the present invention, it is possible to suppress the cooling water flowing through the portion between the first portion and the cylinder bore wall from flowing toward the outlet port side. Accordingly, the flow rate of the cooling water flowing through the portion between the first portion and the cylinder bore wall is reduced compared to the case where the spacer portion facing the outlet port is provided with a notch, and the cylinder bore wall near the outlet port is relaxed. Overcooling can be suppressed. In addition, the first portion has at least a portion on the opening side of the outlet opening facing portion and the outlet opening facing portion located on the cylinder bore side of the center in the width direction of the cooling water flow path. Therefore, the cooling water flowing on the opening side of the spacer main body can smoothly pass between the first portion and the outer inner wall surface and go to the outlet, so the pressure loss of the cooling water led out from the outlet Can be reduced. Furthermore, since the second portion is located on the side opposite to the cylinder bore side from the center in the width direction of the cooling water flow path, a wide passage of the cooling water existing between the second portion and the cylinder bore wall can be secured. . Therefore, the flow rate of the cooling water flowing through the portion between the second portion and the cylinder bore wall is relaxed, and overcooling by the cooling water at the portion of the cylinder bore wall corresponding to the second portion can be suppressed.

The spacer which concerns on this invention WHEREIN: The said 1st part is good also as what is formed so that it may incline in the said upstream from the bottom part side of the said cooling water flow path toward the opening part side of the said cooling water flow path.
According to this, the cooling water upstream of the cooling water channel can be effectively guided to the outlet, and the pressure loss of the cooling water led out from the outlet can be further reduced.

In the spacer according to the present invention, the first portion is formed so that a width along a circumferential direction of the cooling water channel is increased from a bottom side of the cooling water channel to an opening side of the cooling water channel. It is good as it is.
According to this, it is possible to guide more cooling water flowing through the opening side of the cooling water flow path than the spacer body to the outlet, and as a result, further reduce the pressure loss of the cooling water led out from the outlet. be able to.

In the spacer according to the present invention, the first portion is provided with a protrusion protruding toward the outer inner wall surface, and a distance between the protrusion and the outer inner wall surface is set between the second portion and the outer inner wall surface. It may be less than the interval.
According to this, even if the spacer is displaced toward the outer inner wall surface, a large gap is ensured between the first portion and the outer inner wall surface, the cooling water is smoothly led out from the outlet, and the pressure loss can be reduced. Is definitely obtained.
In this case, the projection may be formed to extend linearly toward the outlet opening facing portion.
According to this, since the projection is formed so as to face the outlet opening facing portion, the cooling water that has reached the gap between the first portion and the outer inner wall surface is smoothly led out from the outlet through the guide action of the protrusion. The Further, since the protrusion is linear, the flow resistance of the cooling water flowing through the gap between the first portion and the outer inner wall surface can be suppressed low.
Furthermore, a plurality of the protrusions may be provided, and an interval allowing the coolant to flow between the adjacent protrusions may be ensured.
According to this, since the space | interval which permits the distribution | circulation of cooling water is ensured between adjacent processus | protrusions, Furthermore, since several processus | protrusions are formed so that it may go to an outlet outlet opposing part, 1st The cooling water reaching the gap between the portion and the outer inner wall surface is guided so as to concentrate on the outlet facing portion. Thereby, the cooling water toward the outlet port is not easily subjected to resistance by the protrusion, and is smoothly led out from the outlet port.

The spacer which concerns on this invention WHEREIN: The biasing means which urges | biases the said spacer main body toward the said outer side inner wall surface may be provided in the said cylinder bore side of the said spacer main body.
According to this, even if the spacer body is pressed against the outer inner wall surface by the urging means, a gap through which the cooling water can flow is formed between the first portion and the outer inner wall surface. Smoothly derived from
In this case, the spacer body may be disposed in a part of the cooling water flow path.
According to this, since the spacer main body is arranged in a part of the cooling water flow path, it is easy to be pressed against the outer inner wall surface by the urging means, but in this case as well, it is between the first portion and the outer inner wall surface. Since a gap through which the cooling water can flow is formed, the cooling water is smoothly led out from the outlet.

In the spacer according to the present invention, the urging means is made of a cellulosic sponge that is maintained in a compressed state and is restored to the state before compression by contact with moisture, and is fixed to the cylinder bore side surface of the spacer body. It is good as it is.
According to this, since the spacer can be inserted from the opening of the cooling water flow path in a state where the urging means is maintained in a compressed state, there is a concern that the urging means causes an insertion resistance when inserted. Less is. And after arrange | positioning in a cooling water flow path, cooling water acts on the cellulose sponge of the compressed state as an urging | biasing means, a cellulose sponge restores the state before compression, and the width | variety of a cooling water flow path Enlarging in the direction, the spacer body is urged toward the outer inner wall surface. Since the restored cellulose sponge is positioned so as to oppose the flow of the cooling water flowing in the cooling water flow path, it functions as a regulating means for regulating the flow of the cooling water, and the water flow control performance of the spacer is further improved. Can be improved.

  According to the spacer of the present invention, it is possible to suppress overcooling of the cylinder bore wall in the vicinity of the cooling water outlet, and to reduce the pressure loss when the cooling water is discharged from the outlet.

1 is a schematic perspective view showing a first embodiment of a spacer according to the present invention. It is a schematic plan view which shows the state which has arrange | positioned the spacer of the embodiment in the cooling water flow path of an internal combustion engine. (A) is the side view seen from the A direction in FIG. (B) is the same figure as (a) which shows the modification, (c) is the same figure as (a) which shows another modification. FIG. 3 is a cross-sectional view taken along line B-B in FIG. 2. FIG. 6 is a schematic plan view showing a second embodiment of the spacer according to the present invention and showing a state in which the spacer is arranged in a cooling water flow path of the internal combustion engine. (A) is CC sectional view taken on the line in FIG. 5, (b) is sectional drawing which shows the state which the energizing means contacted with the cooling water and expanded from the state of (a).

  Embodiments of the present invention will be described below with reference to FIGS. 4 and 6 are cross-sectional views taken along the lines BB and CC in FIGS. 2 and 5, respectively. Therefore, in practice, a part of the second part (on the opening side) is structurally used. (Part) is hidden behind the first part and cannot be seen, but is shown so that it can be seen for convenience.

  1 to 4 (a) show a first embodiment of a spacer according to the present invention. The spacer 5 of this embodiment is arrange | positioned in the cooling water flow path 3 of the cylinder block 1 in the internal combustion engine 10, as shown in FIG. The cylinder block 1 is provided with three cylinder bores (cylinders) 2... Connected in series in an adjacent state. 1a... Is an insertion hole for a bolt (not shown) for fastening the cylinder head (see FIG. 6B) to the cylinder block 1 through a head gasket (same as above). Around the three cylinder bores 2, an open deck type groove-shaped cooling water flow path 3 is formed in series. At appropriate positions of the cylinder block 1, an inlet 3 a and an outlet 3 b for cooling water (including antifreeze liquid) communicating with the cooling water flow path 3 are provided. The cooling water outlet 3b is connected to a radiator (not shown) by piping, and the outlet side of the radiator is connected to the cooling water inlet 3a via a water pump (not shown). Thus, the cooling water is configured to circulate between the cooling water flow path 3 and the radiator. In addition, when a cooling water flow path (not shown) is also provided in the cylinder head, the cooling water flow path 3 of the cylinder block 1 and the cooling water flow path of the cylinder head are configured to communicate with each other.

  The cooling water passage 3 is formed in an annular shape so as to surround the three cylinder bores 2. The cooling water passage 3 is formed into a shape having arcuate portions 3c, and constricted portions 3d formed so as to be close to each other between the adjacent cylinder bores 2 and 2. . The groove width of the constricted portion 3d is made larger than the groove width of the other arc-shaped portion 3c of the cooling water flow path 3. And both the inner wall surfaces of the groove-shaped cooling water flow path 3 are made into the shape corresponding to the circular arc shape part 3c ... and the constriction shape part 3d. Both inner wall surfaces of the cooling water passage 3 are constituted by an inner wall surface (inner inner wall surface, outer peripheral surface of the cylinder bore wall 2a) 3e on the cylinder bore 2 side and an inner wall surface (outer inner wall surface) 3f on the opposite side to the cylinder bore 2. The In the illustrated cylinder block 1, the cooling water introduced from the inlet 3 a flows mainly in the direction of the arrow a in the cooling water flow path 3 and is led out from the outlet 3 b. Each cylinder bore 2 is provided with a piston 20 that reciprocates along its axial direction. The piston 20 is in sliding contact with the inner peripheral surface 2aa of the cylinder bore wall 2a via a piston ring 20a attached to the outer peripheral portion thereof. Configured to get.

  The spacer 5 of this embodiment has a cylindrical spacer main body 6 that is inserted into the cooling water channel 3 from the opening 30 and can be disposed over the entire circumference of the cooling water channel 3. The spacer body 6 is made of a rigid synthetic resin molding having rigidity, and the spacer body 6 constitutes most of the spacer 5. The spacer body 6 includes a first portion 61 including a discharge port facing portion 61a (see also FIG. 3) facing the cooling water discharge port 3b, and the cooling water in the cooling water flow path 3 more than the first portion 61. And a second portion 62 connected to the first portion 61 so as to be located on the upstream side in the flow direction a. Here, the upstream side of the cooling water means a direction facing the main flow direction (direction of arrow a) of the cooling water. The spacer body 6 of the present embodiment has a cylindrical shape as described above, and has a shape that substantially conforms to the overall shape of the cooling water passage 3. Therefore, it has the circular arc part 6a ... of the shape corresponding to the circular arc shape part 3c of the cooling water flow path 3, and the convex curved part 6b ... of the shape corresponding to the constriction shape part 3d of the cooling water flow path 3. Further, since the second portion 62 is located on the upstream side of the cooling water from the first portion 61, in this embodiment, a portion other than the first portion 61 in the cylindrical spacer body 6 is the second portion 62. The In other words, the cylindrical spacer body 6 is configured by the first portion 61 and the second portion 62. The first portion 61 is formed in a circular arc portion 6a that is a portion of the spacer body 6 that faces the cooling water outlet 3b.

  Further, the first portion 61 is formed so that the entire first portion 61 is located closer to the cylinder bore 2 than the center b in the width direction of the cooling water passage 3. Further, the entire second portion 62 is formed so as to be located on the side opposite to the cylinder bore 2 side from the center b in the width direction of the cooling water flow path 3. That is, the first portion 61 is formed so as to be recessed with respect to the second portion 62 through the bent wall portions 62a and 62b to the cylinder bore wall 2a side with respect to the center b in the width direction. The bent wall portion 62a and the bent wall portion 62b are located on the upstream side and the downstream side, respectively, with the first portion 61 interposed therebetween. And in this embodiment, the 1st part 61 is formed so that it may incline to the said upstream from the bottom part 31 side of the cooling water flow path 3 toward the opening part 30 side seeing from A direction of FIG. Further, the width D (see FIG. 3A) along the circumferential direction of the cooling water flow path 3 in the first portion 61, that is, the distance D between the two bent wall portions 62a and 62b is the bottom 31 side of the cooling water flow path 3. It forms so that it may become wide toward the opening part 30 side. The bent wall portion 62a is inclined upstream as it goes from the bottom 31 side of the cooling water flow path 3 toward the opening 30 side, while the bent wall portion 62b is moved from the bottom 31 side of the cooling water flow path 3 to the opening 30 side. The further it is, the more it is inclined to the downstream side. In addition, a protrusion 61b that protrudes toward the outer inner wall surface 3f is provided on the outer inner wall surface 3f side of the first portion 61. An interval d1 between the protrusion 61b and the outer inner wall surface 3f is set to be equal to or smaller than an interval d2 between the second portion 62 and the outer inner wall surface 3f. The protrusion amount of the protrusion 61b is equal to or larger than the width dimension of the bent wall portion 62a and the bent wall portion 62b along the width direction of the cooling water flow path 3. Furthermore, the protrusion 61b is formed in a rib shape extending linearly toward the outlet opening facing portion 61a when viewed from the A direction. Specifically, when the protrusion 61b is extended along the first portion 61, the protrusion 61b is formed so as to overlap the outlet opening facing portion 61a. Further, the outlet opening facing portion 61a is located closer to the bottom 31 than the protrusion 61b.

  The spacer 5 configured as described above is arranged in the cooling water flow path 3, and as shown by a two-dot chain line in FIG. 4, the cylinder head 4 is fastened integrally with the upper end surface of the cylinder block 1 via the head gasket 4a. The internal combustion engine 10 is assembled. The head cover 4 is provided with a combustion chamber 40 at a position corresponding to the cylinder bore 2. The head gasket 4 a is interposed between the cylinder block 1 and the cylinder head 4 so as to close the opening 30 of the cooling water flow path 3. During normal operation of the internal combustion engine 10, the piston 20 reciprocates along the axial direction in the cylinder bore 2 due to the explosion and combustion action in the combustion chamber 40. During this time, cooling water is introduced from the inlet 3a and cooled. It circulates in the direction of the arrow a in the water channel 3 and is discharged from the outlet 3b. By circulation of the cooling water in the cooling water flow path 3, the cylinder bore wall 2a is cooled and overheating is suppressed. Further, due to the presence of the spacer 5, the cylinder bore wall 2a is also prevented from being partially cooled by the cooling water.

  And since the 1st part 61 of the spacer 5 exists in the part facing the outlet 3b, the cooling water which flows through the part between the 1st part 61 and the cylinder bore wall 2a is compared with the case where a notch is provided. The flow toward the outlet 3b can be suppressed. Thereby, the flow velocity of the cooling water flowing through the portion between the first portion 61 and the cylinder bore wall 2a is relaxed, and the overcooling of the cylinder bore wall 2a in the vicinity of the outlet 3b can be suppressed. Further, since the first portion 61 is located closer to the cylinder bore 2 than the center b in the width direction of the cooling water flow path 3, the cooling water flowing through the cooling water flow path 3 on the opening 30 side relative to the spacer body 6 is It is possible to smoothly pass between 61 and the outer inner wall surface 3f of the cooling water flow path 3 toward the outlet 3b. Therefore, the pressure loss of the cooling water led out from the outlet 3b can be reduced. Furthermore, since the second portion 62 is located on the opposite side of the center b of the cooling water flow passage 3 in the width direction from the cylinder bore 2 side, the cooling water passage existing between the second portion 62 and the cylinder bore wall 2a is provided. Widely secured. Therefore, the flow velocity of the cooling water flowing through the portion between the second portion 62 and the cylinder bore wall 2a is alleviated, and supercooling by the cooling water on the portion of the cylinder bore wall 2a corresponding to the second portion 62 is suppressed. Can do.

  Furthermore, in this embodiment, the 1st part 61 is formed so that the width along the circumferential direction of the cooling water flow path 3 may become large as it goes to the opening part 30 side from the bottom part 31 side of the cooling water flow path 3. Therefore, the cooling water upstream of the cooling water flow path 3 can be effectively guided to the outlet 3b. Thereby, the pressure loss of the cooling water led out from the outlet 3b can be further reduced. In addition, since the first portion 61 is formed so that the width D along the circumferential direction of the cooling water flow path 3 increases from the bottom side of the cooling water flow path 3 toward the opening 30 side, it is larger than the spacer body 6. More cooling water flowing through the opening 30 side of the cooling water flow path 3 can be guided to the outlet 3b. As a result, the pressure loss of the cooling water led out from the outlet 3b can be reduced more effectively.

  In addition, since the distance d1 between the protrusion 61b provided on the first portion 61 and the outer inner wall surface 3f of the cooling water flow path 3 is set to be equal to or smaller than the distance d2 between the second portion 62 and the outer inner wall surface 3f, the spacer Even if 5 is displaced toward the outer inner wall surface 3 f, the protrusion 61 b contacts the outer inner wall surface 3 f of the cooling water channel 3. Therefore, a large gap is secured between the first portion 61 and the outer inner wall surface 3f, whereby the cooling water is smoothly led out from the outlet 3b, and the effect of reducing the pressure loss can be obtained with certainty. Further, since the protrusion 61b is formed so as to be directed to the outlet opening facing portion 61a, the cooling water reaching the gap between the first portion 61 and the outer inner wall surface 3f is guided to the outlet opening 3b by the protrusion 61b. The The cooling water is smoothly led out from the outlet 3b. In addition, the flow resistance of the cooling water flowing through the gap between the first portion 61 and the outer inner wall surface 3f can be kept low by forming the protrusion 61 in a linear shape facing the outlet opening facing portion 61a.

FIG. 3B is a modification of the present embodiment. In this modification, a plurality of protrusions 61b are provided, and there is an interval between the adjacent protrusions 61b and 61b that allows the coolant to flow. It is configured to be secured. In this example, the cooling water reaching the gap between the first portion 61 and the outer inner wall surface 3f is guided so as to concentrate on the outlet facing portion 61a. Accordingly, the cooling water toward the outlet 3b is not easily subjected to resistance by the plurality of protrusions 61b, and is smoothly led out from the outlet 3b. The shape of the first portion 61 viewed from the A direction is the same as the example of FIG. 3A, and all the protrusions 61b extend the protrusion 61b along the first portion 61 toward the bottom 31 of the cooling water flow path 3. In this case, it is formed so as to overlap the outlet opening facing portion 61a.
FIG. 3C is another modification of the present embodiment, and the shape of the first portion 61 viewed from the A direction is substantially parallel inclined from the bottom 31 side toward the opening 30 side toward the upstream side. It is a quadrilateral. That is, both the bent wall portion 62a and the bent wall portion 62b are inclined to the upstream side as they go from the bottom 31 side of the cooling water flow path 3 to the opening 30 side. Even with such a shape, the cooling water on the upstream side of the cooling water flow path 3 can be effectively guided to the outlet 3b.
In the example of FIG. 3C, one protrusion 61b is provided as in the example of FIG. 3A, but a plurality of protrusions 61b may be provided as in the example of FIG. 3B.

  5 and 6 (a) and 6 (b) show a second embodiment of the spacer according to the present invention. The spacer 5 of the present embodiment is provided with a biasing means 7 that biases the spacer body 6 toward the outer inner wall surface 3 f of the cooling water flow path 3 on the cylinder bore 2 side of the spacer body 6. In the present embodiment, the spacer 5 is constituted by the spacer body 6 and the biasing means 7. Furthermore, the spacer main body 6 of the present embodiment is disposed in a part of the cooling water flow path 3, and the spacer main body 6 of the illustrated example is an arrangement of the cylinder bores 2. The shape is substantially the same as the shape of the right half divided by the center line along the direction. As in the above example, the spacer body 6 includes a first portion 61 including a discharge port facing portion 61a that faces the cooling water discharge port 3b, and a first portion 61 that is positioned on the upstream side of the cooling water from the first portion 61. A second portion 62 connected to the first portion 61. The shape of the first portion 61 viewed from the A direction is the same shape as the example shown in FIGS. The protrusion 61b is also provided on the first portion 61 as in the above example. The biasing means 7 is made of a cellulosic sponge that is maintained in a compressed state and is restored to the state before compression by contact with moisture, and is fixed to the side surface of the cylinder bore 2 of the arc portion 6a in the spacer body 6 by insert molding. Has been. In addition to the cellulose-based sponge, the material constituting the urging means 7 is a foam or non-foamed material that is maintained in a compressed state by a water-swellable sponge, a water-soluble binder, or a binder that dissolves at a temperature equal to or higher than a predetermined temperature. Porous bodies, and those composed of a compression spring and a plate-like body supported by the compression spring are used.

  The spacer 5 of this embodiment is integrated with the spacer body 6 in a state where the urging means 7 is maintained in a compressed state, and is inserted into the cooling water flow path 3 through the opening 30 in this state. 5 and 6A show a state in which the spacer 5 is arranged in the cooling water flow path 3. FIG. At the time of this insertion, since the urging means 7 is in a compressed state, there is little concern that the urging means 7 will cause an insertion resistance. Then, as shown in FIG. 6B, the cylinder head 4 is fastened integrally with the cylinder block 1 in the same manner as described above, and the internal combustion engine 10 is assembled.

Thereafter, when the cooling water w is introduced from the introduction port 3a, the cooling water w comes into contact with the cellulose-based sponge constituting the biasing means 7, and the cellulose-based sponge is restored to the state before compression so that the cooling water flow path 3 Enlarging in the width direction. The surface (cylinder bore side surface) 7 a of the urging means 7 abuts on the inner inner wall surface 3 e of the cooling water flow path 3 due to the restoration and enlargement of the cellulose sponge. As shown in FIG. 6B, the spacer body 6 is displaced by being pressed against the outer inner wall surface 3 f of the cooling water channel 3 by the reaction force accompanying the subsequent restoration of the cellulose-based sponge after the contact. However, since the projection 61b is provided in the first portion 61, the projection 61b contacts the outer inner wall surface 3f of the cooling water flow path 3, and a large gap is ensured between the first portion 61 and the outer inner wall surface 3f. Thus, the cooling water w is smoothly led out from the outlet 3b, and the effect of reducing the pressure loss of the cooling water w is reliably obtained. Further, since the restored cellulose sponge is positioned so as to oppose the flow of the cooling water w flowing in the cooling water flow path 3, it functions as a regulating means for regulating the flow of the cooling water, and the water flow of the spacer 5 Control performance can be further improved.
In the present embodiment, an example is shown in which the biasing means 7 is provided only on the arc portions 6a of the spacer body 6, but it may also be provided on the convex curved portion 6b. Further, the shape of the spacer body 6 is not limited to the half shape as shown in the figure, and may be any other shape as long as it is partially disposed in the cooling water flow path 3, for example, one cylinder bore. It may be an arc shape as viewed from the opening 30 side of the cooling water flow path 3 corresponding to only 2. Since other configurations are the same as those of the first embodiment, common portions are denoted by the same reference numerals, and description thereof is omitted.

In the first embodiment, the spacer body 6 has a cylindrical shape corresponding to the entirety of the annular cooling water flow path 3. However, the spacer main body 6 may have a halved shape similar to the second embodiment. It may be arcuate when viewed from the opening 30 side of the path 3. In the embodiment, the first portion 61 constituting the spacer main body 6 is shaped so that the entirety thereof is located closer to the cylinder bore 2 than the center b in the width direction of the cooling water flow path 3. The 31-side portion may be positioned on the outer inner wall surface 3f side from the width direction center b. Moreover, although the spacer main body 6 described the example which consists of a synthetic resin molding, you may consist of materials with rigidity, such as a metal. In particular, in the case of the second embodiment, other materials may be used as long as they are more rigid than the materials constituting the urging means 7.
Furthermore, the length of the protrusion 61 b may be changed as appropriate, and the protrusion 61 b may be extended along the first portion 61 toward the opening 30 of the cooling water flow path 3. Further, the protrusion 61b is not limited to a shape extending toward the outlet opening facing portion 61a. For example, the protrusion 61b may be changed to a shape that extends in a direction not toward the outlet opening facing portion 61a as long as the flow of the cooling water is not excessively inhibited. Further, the protrusion 61b is not limited to a shape extending linearly, and may be changed to a shape extending in a curved shape or may be changed to a dot shape.
In addition, although the three-cylinder internal combustion engine is exemplified as the internal combustion engine to which the spacer of the present invention is applied, the present invention is not limited to this and can be applied to an internal combustion engine having other number of cylinders.

  In addition, various types of cellulosic sponges are exemplified, but not particularly limited. For example, a fine product having a very small bubble size, a small product having a small bubble size, or a medium product having a moderate bubble size may be used. Specifically, a cellulosic sponge having a bubble size (diameter) of about 0.1 to 5 mm may be used. The size of these bubbles is determined by the particle size of the crystalline graphite used in the process of producing the cellulosic sponge. Cellulose-based sponges may be composed of cellulose alone in addition to cellulose and reinforcing fibers. In addition to the sponge made of cellulose itself, the cellulose-based sponge is a cellulose derivative that retains the hydroxyl group of cellulose to such an extent that the compressed state can be maintained, for example, a sponge made of cellulose ethers, cellulose esters, or the like, or It may be selected from any of sponges made of these mixtures.

DESCRIPTION OF SYMBOLS 1 Cylinder block 2 Cylinder bore 3 Cooling water flow path 3b Cooling water outflow port 3f Outer inner wall surface 30 of cooling water flow path 30 Opening part 31 Bottom part 5 Spacer 6 Spacer main body 61 1st part 61a Outlet outlet opposing part 61b Protrusion 7 Energizing means 10 Internal combustion Engine a Flow direction of cooling water b Center of width direction of cooling water channel d1 Distance between protrusion and outer inner wall surface of cooling water channel d2 Distance between second part and outer inner wall surface of cooling water channel D Circumferential direction of first part Width along

Claims (9)

A spacer disposed in a cooling water passage formed in a cylinder block of an internal combustion engine so as to surround a cylinder bore and provided with a cooling water outlet on an outer inner wall surface opposite to the cylinder bore,
A spacer body having a shape that can be disposed in the cooling water flow path;
The spacer body includes a first portion including a discharge port facing portion that faces the cooling water discharge port, and is positioned upstream of the first portion in the cooling water flow direction in the cooling water flow path. A second part connected to the first part,
The first portion is formed such that at least the outlet opening facing portion and the opening side of the cooling water passage from the outlet facing portion are located on the cylinder bore side of the center in the width direction of the cooling water passage. ,
The spacer is characterized in that the second portion is formed so as to be located on the opposite side to the cylinder bore side from the center in the width direction of the cooling water passage. The spacer according to claim 1,
The spacer is characterized in that the first portion is formed so as to be inclined toward the upstream side from the bottom side of the cooling water channel toward the opening side of the cooling water channel. The spacer according to claim 1 or 2,
The first portion is formed so that a width along a circumferential direction of the cooling water channel is widened from a bottom side of the cooling water channel toward an opening side of the cooling water channel. . The spacer according to any one of claims 1 to 3,
The first portion is provided with a protrusion that protrudes toward the outer inner wall surface, and a distance between the protrusion and the outer inner wall surface is equal to or less than a distance between the second portion and the outer inner wall surface. A spacer characterized by. The spacer according to claim 4,
The said protrusion is formed so that it may extend linearly toward the said outlet opening opposing part. The spacer according to claim 4 or claim 5,
A plurality of the protrusions are provided, and an interval allowing the coolant to flow is secured between adjacent protrusions. The spacer according to any one of claims 1 to 6,
An urging means for urging the spacer body toward the outer inner wall surface is provided on the cylinder bore side of the spacer body. The spacer according to claim 7,
The spacer body is arranged at a part of the cooling water flow path. The spacer according to claim 7 or claim 8,
The urging means is made of a cellulosic sponge that is maintained in a compressed state and is restored to its pre-compression state by contact with moisture, and is fixed to a cylinder bore side surface of the spacer body. .

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