JP2020104656A - Work vehicle - Google Patents

Abstract

To provide a work vehicle that is able to suitably rectify a flow of air taken into a bonnet from a vent hole.SOLUTION: A work vehicle comprises: a cooling fan by which air outside a bonnet 10 is taken inside via a vent hole 30; a cooling unit 90 that is provided in the bonnet 10 and in front of the cooling fan 40 and cools a fluid to be cooled with air taken by the cooling fan 40; and a pair of rectifying plates 100 (a right rectifying plate 110 and a left rectifying plate 150) provided in the bonnet 10 and between the vent 30 and the cooling unit 90 and having notches (a right notch 120 and a left notch 160) that are substantially rectangular in shape as viewed from a side and are open at front and at top.SELECTED DRAWING: Figure 10

Description

The present invention relates to a technique of a work vehicle including a cooling unit that cools a fluid such as oil by air taken into a bonnet.

2. Description of the Related Art Conventionally, a technique of a work vehicle including a cooling unit that cools a fluid such as oil by air taken in a bonnet has been publicly known. For example, it is as described in Patent Document 1.

Patent Document 1 describes a tractor that includes a radiator, an oil cooler, an intercooler, and the like as a cooling unit that cools a fluid. The tractor is provided with straightening vanes on the left and right sides of the radiator, respectively. Thus, in the tractor, the intake of air from the side of the radiator to the radiator and the like is restricted.

However, in the tractor described in Patent Document 1, it is only necessary to restrict intake of air into the radiator or the like from the side of the radiator by the flow straightening plate, and for example, in the case of having ventilation holes on the left and right side portions of the bonnet. However, there is no consideration in adjusting the flow of the air taken in from the ventilation hole.

JP, 2017-226326, A

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a work vehicle capable of appropriately adjusting the flow of air taken into the inside of the hood from the ventilation hole. is there.

The problem to be solved by the present invention is as described above, and means for solving the problem will be described below.

That is, in claim 1, a bonnet having vent holes on the left and right sides, a fan provided inside the bonnet, and taking in air outside the bonnet through the vent holes, and an inside of the bonnet A cooling unit that is provided in front of the fan to cool the fluid to be cooled by the air taken in by the fan, and is provided between the vent hole and the cooling unit inside the bonnet, and a side surface. It is provided with a pair of straightening vanes each having a substantially rectangular shape as viewed and having a notched portion whose front side and upper side are opened.

According to a second aspect of the present invention, the cutout portion has a corner portion having an angle of two sides of about 90 degrees.

According to a third aspect of the present invention, the cutout portions of the pair of straightening vanes include a cutout portion having a step-like step that descends forward.

According to a fourth aspect of the present invention, the cutout portions of the pair of straightening vanes include cutout portions in which the corner portions of the mouth opened to the front are formed in a cutout shape.

In Claim 5, The said ventilation hole of the said bonnet has a 1st part which overlaps with the said straightening vane in side view, and a 2nd part which does not overlap, The said 2nd part is the lower end part of the said notch part. Is provided so as to straddle in the vertical direction.

The cooling unit according to claim 6, wherein the cooling unit includes a plurality of coolers whose objects to be cooled are different from each other, and the plurality of coolers are provided in front of the first cooler and the first cooler. A second cooler whose height position of the upper end portion is lower than that of the first cooler; It includes a notch portion provided at a position spaced apart from the front to the front.

In a seventh aspect, the cutout portions of the pair of straightening vanes include a cutout portion provided above the second cooler in a side view.

In claim 8, the second cooler includes a third cooler and a fourth cooler provided in front of the third cooler, and the third cooler and the The fourth cooler is provided such that the left and right one sides do not overlap with each other in the front view and the other left and right sides overlap with each other, and the cutout portions of the pair of straightening plates are more than the cutout portions on the left and right one sides in a side view. The notch on the other side of the left and right sides is formed larger.

The effects of the present invention are as follows.

In the first aspect, the flow of the air taken into the inside of the bonnet from the ventilation hole can be suitably adjusted by the pair of straightening vanes.

In the second aspect, since the notch has the corner, more air can be taken into the corner. Accordingly, when the heat is stagnant or concentrated, or when more air is desired to flow, it is possible to efficiently guide the air by providing the corner portion in the vicinity of the necessary portion.

According to the present invention, even in the cutout portion of the straightening vane, there is a step so that the air existing between the vent hole and the straightening vane after being taken in from the vent hole is different from each other in the front-rear direction position. Can be guided to the front of the cooling unit.

In the fourth aspect, the air between the ventilation hole and the straightening plate after being taken in from the ventilation hole can be guided to the front of the cooling unit as smoothly as possible through the straightening plate.

In the fifth aspect, the air guided to the front of the cooling unit can include not only the air guided through the straightening vanes but also the air guided without the straightening vanes.

In the sixth aspect, the air whose temperature has not risen (air which has not passed through the second cooler) can be supplied to the first cooler.

In claim 7, since the air guided from the cutout portion of the baffle plate to the front of the cooling unit is not supplied to the second cooler, an excessive amount of air is supplied to the second cooler. Can be suppressed.

In claim 8, a relatively large amount of air can be guided to a side where the third cooler and the fourth cooler overlap in a front view, and a relatively small amount of air can be guided to a side that does not overlap. it can.

The right side view showing the whole tractor composition concerning one embodiment of the present invention. Similarly, the perspective view which showed the front part of the tractor. The perspective view which showed the inside of a bonnet. The partially expanded perspective view which showed the inside of a bonnet. The left side view showing the right side current plate and the right side air intake. FIG. 5 is a right side view showing the left flow plate and the left intake port. The right view which showed the arrangement structure of the circumference of a cooler. The left side view showing the arrangement composition of the circumference of a cooler. The top view which showed the arrangement structure of the circumference of a cooler. The right side schematic diagram which showed a mode that air flows into a cooler. The left side schematic diagram which showed a mode that air flows into a cooler. FIG. 4 is a right side plan view showing how air flows to the cooler. FIG. 5 is a left side plan view showing how air flows to the cooler. The front view which showed the oil introduction/extraction structure. The perspective view which showed the oil introduction/extraction structure. (A) The right side view which showed the oil cooler and the oil introduction/extraction structure. (B) The figure which abbreviate|omitted a part of Fig.16 (a). (A) The front view which showed the downstream side edge part of an oil outward path. (B) The front sectional view of FIG. (A) The front view which showed the check valve. (B) A front sectional view showing a check valve. (A) A front sectional view showing an intermediate member of the check valve. (B) A front exploded sectional view showing an intermediate member of the check valve. The front sectional view showing the intermediate member of the check valve in an opened state. FIG. 3 is a front cross-sectional view showing an oil introducing/extracting structure. The disassembled perspective view which showed the oil introduction/extraction structure. (A) A schematic front cross-sectional view showing the check valve before the change of the total length. (B) A schematic front cross-sectional view showing the check valve after the total length is changed. The front cross-sectional schematic diagram which showed the circulation mode of the oil in the oil introducing/extracting structure when a check valve is a closed state. The front cross-sectional schematic diagram which showed the circulation mode of the oil in the oil introducing/extracting structure when a check valve is an open state. (A) The front view which showed the block joint and stay. (B) The top view which showed the block joint and stay. (A) A right side view showing a block joint and a stay. (B) Partial right side sectional view showing the block joint and the stay. The right side view showing the attachment state of the block joint. The partial side sectional view showing the pipe connection state of the block joint. The front view which showed the attachment state of the block joint. FIG. 31 is a partially enlarged view of FIG. 30.

In the following, the directions indicated by arrows U, D, F, B, L and R in the figure are defined as upward, downward, forward, backward, leftward and rightward, respectively. And explain.

First, the overall configuration of the tractor 1 according to the embodiment of the present invention will be described with reference to FIGS. 1 to 4. Note that, in FIG. 4, a capacitor 80 and a right rectifying plate 110, which will be described later, are omitted from the configuration illustrated in FIG. 3 for convenience.

The tractor 1 mainly includes a body frame 2, an engine 3, a flywheel housing 4, a clutch housing 5, a transmission case 6, a lifting device 7, front wheels 8, rear wheels 9, a bonnet 10, a muffler 11, a cabin 12, a steering wheel 13, and a seat. 14 and so on.

The machine body frame 2 is a frame-shaped member formed by appropriately combining a plurality of plate materials. The machine body frame 2 is arranged in the lower front part of the tractor 1 with its longitudinal direction oriented in the front-rear direction. The engine 3 is fixed to the rear portion of the machine body frame 2. A flywheel housing 4 is fixed to the rear portion of the engine 3. A clutch housing 5 is fixed to the rear part of the flywheel housing 4. A transmission case 6 is fixed to the rear part of the clutch housing 5. An elevating device 7 is provided at the rear of the transmission case 6. Various work devices (for example, a cultivator) can be attached to the lifting device 7.

The front portion of the machine body frame 2 is supported by a pair of left and right front wheels 8 via a front axle mechanism (not shown). The transmission case 6 is supported by a pair of left and right rear wheels 9 via a rear axle mechanism (not shown).

The engine 3 is covered with the hood 10. The bonnet 10 is rotatably supported by a bonnet support member 24 fixed to the upper portion of the flywheel housing 4 shown in FIG. As shown in FIGS. 3 and 4, inside the bonnet 10, a cooling fan 40 is provided in front of the engine 3. A cooling unit 90 cooled by the cooling fan 40, the battery 16, and an air cleaner 17 are provided in front of the cooling fan 40. Straightening vanes 100 are provided on the left and right sides of the cooling unit 90. A muffler 11 that discharges exhaust gas of the engine 3 is arranged on the left side of the hood 10. A cabin 12 is provided behind the bonnet 10. Inside the cabin 12, a steering wheel 13, a seat 14, various operating tools, pedals and the like are arranged.

Further, the power of the engine 3 is transmitted to a front wheel 8 via the front axle mechanism after being changed by a transmission (not shown) housed in the transmission case 6, and is also transmitted via the rear axle mechanism to the rear wheel mechanism. It can be transmitted to the wheel 9. In this way, the front wheels 8 and the rear wheels 9 are rotationally driven by the power of the engine 3, and the tractor 1 can travel. Further, the power of the engine 3 can drive the working device mounted on the lifting device 7. Further, the cooling fan 40 can be driven by the power of the engine 3.

Hereinafter, the configuration of the hood 10 will be described in detail with reference to FIGS. 2, 5, and 6.

The bonnet 10 is formed in a substantially box-like shape with its rear and lower portions open. The bonnet 10 includes an upper surface portion 26, a front surface portion 27, and a side surface portion 28.

The upper surface portion 26 constitutes a top plate of the bonnet 10. The upper surface portion 26 is formed in a shape that inclines downward as it goes forward. The front portion of the upper surface portion 26 is formed in a tapered shape as it goes forward in a plan view.

The front surface portion 27 constitutes a front plate of the bonnet 10. The upper end of the front surface portion 27 is connected to the front end of the upper surface portion 26.

The side surface portion 28 constitutes left and right side plates of the bonnet 10. The side surface portion 28 is formed in a substantially rectangular shape such that the rear lower portion is cut out in a side view. The upper end of the side surface portion 28 is connected to the left and right ends of the upper surface portion 26. Further, the front end of the side surface portion 28 is connected to the left and right side ends of the front surface portion 27. The side surface portion 28 includes a ventilation hole 30.

The ventilation hole 30 is a portion for sucking outside air into the inside of the bonnet 10. The ventilation hole 30 is configured by providing a mesh member with respect to an opening that penetrates the side surface portion 28. The ventilation hole 30 is formed near the front end of the side surface portion 28. The vent hole 30 is formed in a substantially rectangular shape such that the width in the vertical direction becomes smaller as it goes forward when viewed from the side. The ventilation holes 30 are formed on the left and right sides of the side surface portion 28, respectively. As shown in FIGS. 5 and 6, the left and right vent holes 30 are formed in a bilaterally symmetrical shape.

Air is taken into the ventilation holes 30 by driving the cooling fan 40. The air taken in through the air holes 30 has its flow regulated by the current plate 100, and is guided to the cooling unit 90 (the radiator 50, the oil cooler 60, the fuel cooler 70, and the condenser 80). In the following description, the right vent 30 will be referred to as the "right vent 31", and the left vent 30 will be referred to as the "left vent 32".

Hereinafter, a configuration in which the air taken in from the right vent hole 31 and the left vent hole 32 is guided to the cooling unit 90 by the straightening plate 100 will be described in detail.

The cooling unit 90 is an assembly of coolers that cool the fluid to be cooled. In the present embodiment, the cooling unit 90 includes the radiator 50, the oil cooler 60, the fuel cooler 70, and the condenser 80.

First, the configuration of the current plate 100 will be described in detail with reference to FIGS. 5 and 6.

The current plate 100 is provided on the left and right sides of the cooling unit 90 as described above. In the following, the right flow plate 100 will be referred to as the “right flow plate 110”, and the left flow plate 100 will be referred to as the “left flow plate 150”.

The right side current plate 110 shown in FIG. 5 mainly regulates the flow of the air taken in from the right side ventilation hole 31. The right side current plate 110 is formed of a plate-shaped member having a substantially rectangular shape in a side view with the plate surface facing left and right. The right side current plate 110 is erected upward from the substantially flat plate-shaped support base 21 mounted on the machine body frame 2 (see FIG. 3 ). The right flow plate 110 includes a right first portion 111, a right second portion 112, and a right cutout 120.

The right-side first portion 111 is a portion that is provided below the right-side current plate 110 and has a substantially rectangular shape in a side view. The front end of the right first portion 111 constitutes the front end of the right flow plate 110. That is, the front end of the right first portion 111 is located at the same place as the front end of the right flow plate 110. In the following, the position of the front end of the right side first portion 111 in the front-rear direction will be referred to as "front side position RF1". Further, the upper end of the right side first portion is located at a height of about a little less than 3/4 of the height of the right side current plate 110. In addition, below, the position of the upper end of the right side first portion 111 in the vertical direction is referred to as “height position RH1”.

The right side second portion 112 is a portion which is provided on the right side current plate 110 and has a substantially rectangular shape in a side view. The right side second portion 112 is integrally formed with the right side first portion 111. The front end of the right second portion 112 is located rearward of the front end of the right flow plate 110. More specifically, the front end of the right side second portion 112 is located slightly rearward of the central portion of the right side current plate 110 in the front-rear direction. In the following, the position of the front end of the right side second portion 112 in the front-rear direction will be referred to as the “front side position RF2”. Further, the upper end of the right side second portion constitutes the upper end of the right side current plate 110. That is, the upper end of the right side second portion 112 is located at the same place as the upper end of the right side current plate 110. In addition, below, the position of the upper end of the right side second portion 112 in the vertical direction is referred to as “height position RH2”.

The right cutout portion 120 is a portion formed by appropriately cutting out the right flow plate 110. The right cutout 120 includes a right first cutout 121, a right second cutout 122, and a right third cutout 123.

The right-side first notch 121 is a notch formed so as to be surrounded by the upper end of the right-side first portion 111 and the front end of the right-side second portion 112. That is, the right side first cutout 121 is formed so that the upper side and the front side are open. The rear end of the right first notch 121 is located at the front position RF2 in the front-rear direction. In addition, the lower end of the right side first cutout portion 121 is located at a height position RH1 in the vertical direction. Further, the front end of the right first notch 121 is located at the front position RF1 in the front-rear direction. The right side first cutout portion 121 has a right side corner portion 131.

The right corner 131 is a part located at the rear lower end of the right first notch 121. The right corner 131 is formed at a portion where the rear end (rear side) and the lower end (lower side) of the right first cutout 121 intersect. That is, the right corner 131 is formed by the upper end of the right first portion 111 of the right flow plate 110 and the front end of the right second portion 112 so that the angle between the two sides is approximately 90 degrees in a side view.

The right second cutout 122 is a cutout formed by cutting out the front upper end of the right first portion 111. In other words, the right second notch 122 is a notch in which the corner of the mouth opened to the front of the right first notch 121 is formed in a notch shape. The right second notch 122 has an oblique linear edge portion whose upper end is located rearward and whose lower end is located forward.

The right side third cutout portion 123 is a cutout portion formed by cutting out the front upper end portion of the right side second portion 112. In other words, the right side third cutout portion 123 is a cutout portion in which the corner portion of the mouth opened above the right side first cutout portion 121 is formed in a cutout shape. The right third notch 123 has an oblique linear edge portion whose upper end is located rearward and whose lower end is located forward.

In this way, the right side current plate 110 is formed in a substantially rectangular shape that is long in the vertical direction as a whole, and is formed into a shape (generally L-shaped) that is appropriately cut away from the front to the rear. A right vent hole 31 is arranged on the right side of the right flow plate 110 (on the back side of the plane of FIG. 5).

Here, comparing the shapes of the right vent hole 31 and the right flow plate 110 with each other in a side view, the right vent hole 31 and the right flow plate 110 may overlap with each other except a part of the right vent hole 31 on the front side. Is formed. In the following, a part of the right vent hole 31 on the front side is referred to as a "non-overlapping part 31a".

The non-overlapping portion 31a of the right vent hole 31 is formed in a substantially V shape that is open rearward in a side view. The upper portion of the non-overlapping portion 31a is located in front of the lower portion of the right second portion 112 of the right flow plate 110 in a side view, and is formed to overlap the lower portion of the right first cutout portion 121. Further, the lower portion of the non-overlapping portion 31a is located in front of the upper portion of the right first portion 111 in a side view and is formed so as to overlap with the space in front of the right first cutout portion 121 and the upper portion of the right first portion 111. It

In this manner, the non-overlapping portion 31a of the right vent hole 31 vertically extends over the boundary portion between the right first notch 121 and the right first portion 111 (the lower end of the right first notch 121) in the side view. It is formed.

The left side current plate 150 shown in FIG. 6 mainly regulates the flow of the air taken in from the left vent 32. The left side current plate 150 is formed of a plate-shaped member having a substantially rectangular shape in a side view with the plate surface facing left and right. Like the right side current plate 110, the left side current plate 150 is erected upward from the support base 21 mounted on the machine body frame 2. The left side current plate 150 includes a left side first portion 151, a left side second portion 152, a left side third portion 153, and a left side cutout 160.

The left-side first portion 151 is a portion that is provided in the lower portion of the left-side rectifying plate 150 and has a substantially rectangular shape in a side view. The front end of the left first portion 151 constitutes the front end of the left flow plate 150. That is, the front end of the left first portion 151 is located at the same position as the front end of the left flow plate 150. In the following, the position of the front end of the left first portion 151 in the front-rear direction will be referred to as the "front position LF1". Further, the upper end of the left first portion 151 is located slightly above the vertical center of the left straightening plate 150. In addition, below, the position of the upper end of the left side first portion 151 in the vertical direction is referred to as “height position LH1”. The height position LH1 is formed at a position lower than the height position RH1 of the right flow plate 110.

The second left side portion 152 is a substantially rectangular portion in a side view, which is provided in the upper and lower middle portions of the left side current plate 150. The left side second portion 152 is integrally formed with the left side first portion 151. The front end of the left side second portion 152 is located rearward of the front end of the left side current plate 150. More specifically, the front end of the second left portion 152 is located slightly forward of the front-rear center portion of the left flow plate 150. In the following, the position of the front end of the left side second portion 152 in the front-rear direction will be referred to as the "front side position LF2". Further, the upper end of the left side second portion is located at a height of about 3/4 of the height of the left side current plate 150. In addition, below, the position of the upper end of the left side second portion 152 in the vertical direction is referred to as “height position LH2”. The height position LH2 is formed at a position higher than the height position RH1 of the right flow plate 110.

The left side third portion 153 is a portion that is provided on the left side current plate 150 and has a substantially rectangular shape in a side view. The left side third portion 153 is integrally formed with the left side second portion 152. The front end of the left side third portion 153 is located slightly rearward of the central portion of the left side current plate 150 in the front-rear direction. In the following, the position of the front end of the left side third portion 153 in the front-rear direction will be referred to as the “front side position LF3”. Further, the upper end of the left third portion constitutes the upper end of the left flow plate 150. That is, the upper end of the left third portion 153 is located at the same position as the upper end of the left flow plate 150. In addition, below, the position of the upper end of the left side third portion 153 in the vertical direction is referred to as “height position LH3”.

The front side position LF3 of the left side third portion 153 is located at the same position as the front side position RF2 of the right side current plate 110 in the front-rear direction. That is, the length of the left third portion 153 in the front-rear direction is formed to be the same as the length of the right second portion 112 of the right flow plate 110 in the front-rear direction.

The left cutout 160 is a portion formed by appropriately cutting out the left flow plate 150. The left notch 160 includes a left first notch 161, a left second notch 162, a left third notch 163, and a left fourth notch 164.

The left first notch 161 is a notch formed so as to be surrounded by the upper end of the left second part 152 and the front end of the left third part 153. That is, the left first notch 161 is formed so that the upper side and the front side are open. The rear end of the left first notch 161 is located at the front position LF3 in the front-rear direction. Further, the lower end of the left first notch 161 is located at the height position LH2 in the vertical direction. Further, the front end of the left first notch 161 is located at the front position LF1 in the front-rear direction. The left all first cutout 161 has a left first corner 171.

The left first corner 171 is a portion located at the rear lower end of the left first notch 161. The left first corner 171 is formed at a portion where the rear end (rear side) and the lower end (lower side) of the left first all-notch portion 161 intersect. That is, the left first corner portion 171 is formed by the upper end of the left second portion 152 of the left flow plate 150 and the front end of the left third portion 153 so that the angle between the two sides is approximately 90 degrees in a side view. ..

The left side second cutout 162 is a cutout formed so as to be surrounded by the upper end of the left side first portion 151 and the front end of the left side second portion 152. That is, the left second notch 162 is formed such that the upper side and the front side are open. The rear end of the left second notch 162 is located at the front position LF2 in the front-rear direction. Further, the lower end of the left second notch 162 is located at the height position LH1 in the vertical direction. Further, the front end of the left second notch portion 162 is located at the front position LF1 in the front-rear direction. The left side second cutout portion 162 has a left side second corner portion 172.

The left second corner portion 172 is a portion located at the rear lower end of the left second notch portion 162. The left second corner 172 is formed at a portion where the rear end (rear side) and the lower end (lower side) of the left second notch 162 intersect. That is, the left side second corner portion 172 is formed by the upper end of the left side first portion 151 of the left side current plate 150 and the front end of the left side second portion 152 so that the angle between the two sides is approximately 90 degrees in a side view.

The left side third cutout portion 163 is a cutout portion formed by cutting out the front upper end portion of the left side first portion 151. In other words, the left third notch 163 is a notch in which the corner of the mouth opened to the front of the left second notch 162 is notched. The left third cutout portion 163 has an oblique linear edge portion whose upper end is located rearward and whose lower end is located forward.

The left side fourth cutout portion 164 is a cutout portion formed by cutting out the front upper end portion of the left side third portion 153. In other words, the left side fourth cutout portion 164 is a cutout portion in which the corner portion of the mouth opened above the left side first cutout portion 161 is formed in a cutout shape. The left-side fourth cutout portion 164 has an oblique linear edge portion whose upper end is located rearward and whose lower end is located forward.

In this way, the left side current plate 150 is formed in a generally rectangular shape that is long in the up-down direction in a side view as a whole, and has a shape (generally L-shaped) that is appropriately cut away from the front to the rear. .. Further, the left side current plate 150 is formed in a step-like shape having a step that is lowered as it goes forward, by the first left side cutout 161 and the left side second cutout 162. A left vent 32 is arranged on the left side of the left flow plate 150 (on the back side of the plane of FIG. 6).

Here, comparing the shapes of the left vent hole 32 and the left rectifying plate 150 in a side view, the left vent hole 32 and the left rectifying plate 150 are overlapped with each other except a part of the front side of the left vent hole 32. Is formed. In the following, a part of the front side of the left vent 32 will be referred to as a "non-overlapping part 32a".

The non-overlapping portion 32a of the left ventilation hole 32 is formed in a substantially V shape that is open rearward in a side view. The upper portion of the non-overlapping portion 32a is located in front of the lower portion of the left third portion 153 of the left flow plate 150 in a side view, and is formed so as to overlap the lower portion of the left first cutout portion 161. Further, the central portion of the non-overlapping portion 32a is located in front of the left side second portion 152 of the left side current plate 150 in a side view and is formed so as to overlap the left side second cutout portion 162. Further, the lower portion of the non-overlapping portion 32a is located in front of the upper portion of the left first portion 151 in a side view, and is formed so as to overlap the space in front of the upper portions of the left third cutout portion 163 and the left first portion 151. ..

In this way, the non-overlapping portion 32a of the left vent 32 has a boundary between the left first notch 161 and the left second notch 162, a left second notch 162 and a left third notch 163 in a side view. Is formed so as to straddle each of the boundary portions in the vertical direction. In other words, the non-overlapping portion 32a of the left vent 32 is formed so as to straddle the lower end of the left first notch 161 and the lower end of the second left notch 162 in the vertical direction.

In addition, the overall size of the left cutout 160 is larger than the overall size of the right cutout 120 of the right flow plate 110.

Hereinafter, the configurations of the cooling unit 90 (the radiator 50, the oil cooler 60, the fuel cooler 70, and the condenser 80) shown in FIGS. 3 and 4 and the cooling fan 40 arranged behind the cooling unit 90 will be described.

The cooling fan 40 is configured to be rotatable by the power of the engine 3. The cooling fan 40 includes a fan shroud 41.

The fan shroud 41 houses the cooling fan 40 and a part of the radiator 50. The fan shroud 41 is formed so as to penetrate in the front-rear direction at the inner portion (the place where the cooling fan 40 is housed). The fan shroud 41 is fixed to the machine body frame 2 and stands upright from the machine body frame 2.

The outer edge of the fan shroud 41 is provided so as to close the gap between the fan shroud 41 and the inner surface of the bonnet 10 (not shown). Thus, inside the hood 10, the fan shroud 41 divides the front space and the rear space from each other, and the front space and the rear space are separated from each other only through the inner portion of the fan shroud 41. It is formed so as to communicate with each other.

The radiator 50 cools the cooling water of the engine 3. The radiator 50 is configured to be able to circulate cooling water between the radiator 50 and the engine 3. The radiator 50 includes a radiator core 51 and an upper tank 52.

The radiator core 51 has a plurality of tubes through which cooling water flows and a plurality of radiating fins. The radiator core 51 has a substantially rectangular outer shape when viewed from the front, and is configured to allow air to pass from the front to the rear. The upper tank 52 is formed so as to cover the upper end of the radiator core 51 from above.

In this way, the radiator 50 is fixed to the machine body frame 2 while the lower end portion is housed in the fan shroud 41. The radiator core 51 of the radiator 50 faces the cooling fan 40 in the front-rear direction inside the fan shroud 41.

The oil cooler 60 shown in FIG. 4 cools oil (operating oil) of a predetermined hydraulic device or the like. The oil cooler 60 is configured to be able to circulate oil with the hydraulic equipment and the like. The oil cooler 60 has a substantially rectangular outer shape when viewed from the front. The oil cooler 60 has a tube 61 through which oil flows and heat radiation fins, and is configured to allow air to pass from the front to the rear. The oil cooler 60 is erected above the support base 21 via a predetermined frame.

Further, the oil cooler 60 is provided with an introduction port 62 into which oil is introduced and an outflow port 63 from which oil is led out (see FIG. 14 ). To the introduction port 62, one end of the oil outward path 200 through which oil flows is connected. A block joint 250 is connected to an intermediate part of the oil outward path 200 (see FIG. 3 ). One end of an oil return path 300 through which oil flows is connected to the outlet port 63. A check valve 400 for the oil cooler 60 is provided on the right side of the oil cooler 60. Thus, on the right side of the oil cooler 60, a structure in which oil is introduced into the oil cooler 60 and a structure in which oil is led out from the oil cooler 60 (hereinafter referred to as “oil introduction/extraction structure”) are provided. .. A detailed description of the oil introduction/extraction structure will be given later. A detailed description of the structure of the block joint 250 will be given later.

The fuel cooler 70 cools the fuel used in the engine 3. The fuel cooler 70 has a substantially rectangular outer shape when viewed from the front. The fuel cooler 70 has tubes and radiating fins through which fuel flows, and is configured to allow air to pass from front to back. The fuel cooler 70 is erected above the support base 21 via a predetermined frame.

The condenser 80 cools the refrigerant used in the air conditioner. The capacitor 80 has a substantially rectangular outer shape when viewed from the front. The condenser 80 has a tube through which a refrigerant flows and a radiation fin, and is configured to allow air to pass from the front to the rear. The capacitor 80 is erected above the support base 21 via a predetermined frame.

Hereinafter, the positional relationship between the cooling unit 90 (the radiator 50, the oil cooler 60, the fuel cooler 70, and the condenser 80) and the right side current plate 110 and the left side current plate 150 will be described in detail with reference to FIGS. 7 to 9. explain.

As shown in FIGS. 7 to 9, a radiator 50 is arranged in front of the cooling fan 40. The radiator 50 is provided so as to extend vertically and horizontally with respect to an inner portion (a portion that penetrates in the front-rear direction) of the fan shroud 41 that accommodates the cooling fan 40. An oil cooler 60 and a fuel cooler 70 are arranged in front of the radiator 50.

The fuel cooler 70 is arranged above the oil cooler 60. That is, the fuel cooler 70 and the oil cooler 60 are located at the same place in the front-rear direction. Further, the upper end of the fuel cooler 70 is formed to be lower than the upper end of the radiator 50.

Further, the oil cooler 60 and the fuel cooler 70 are formed so that the lengths in the left-right direction are substantially the same. The horizontal lengths of the oil cooler 60 and the fuel cooler 70 are smaller than the horizontal length of the radiator 50. Further, the oil cooler 60 and the fuel cooler 70 are arranged in front of the radiator 50 and at positions closer to the left side with respect to the radiator 50. That is, the left ends of the oil cooler 60 and the fuel cooler 70 are located at substantially the same position as the left end of the radiator 50 in the left-right direction position. Further, the right ends of the oil cooler 60 and the fuel cooler 70 are located to the left of the right end of the radiator 50 in the lateral position. A condenser 80 is arranged in front of the oil cooler 60 and the fuel cooler 70.

The capacitor 80 is formed so that the length in the left-right direction is substantially the same as that of the radiator 50. Further, the upper end of the condenser 80 is formed to have substantially the same height as the upper end of the fuel cooler 70.

Due to such a positional relationship, no other cooler is arranged in front of the upper range R1 of the radiator 50. Further, in front of the lower range R2 of the radiator 50, the condenser 80, the oil cooler 60 and the fuel cooler 70 are arranged in front of the left range R3, and only the condenser 80 is arranged in front of the right range R4. Has been done.

As shown in FIGS. 7 and 9, the right flow plate 110 is arranged between the right vent hole 31 and the cooling unit 90, and is arranged so as to extend forward from the right end of the radiator 50 of the cooling unit 90. It The front end of the right flow plate 110 is located in front of the condenser 80. That is, the right flow plate 110 is arranged so as to cover the cooling unit 90 (the radiator 50, the oil cooler 60, the fuel cooler 70, and the condenser 80) from the right side.

The rear end of the first right notch 121 of the right flow plate 110 (the front side position RF2 of the right flow plate 110) is formed to be located above the oil cooler 60 and the fuel cooler 70 in a side view. Further, the lower end of the first right notch 121 of the right flow plate 110 (the height position RH1 of the right flow plate 110) is slightly higher than the upper ends of the condenser 80, the oil cooler 60, and the fuel cooler 70 in a side view. Highly formed. The upper end and the lower end (the height position RH2 and the height position RH1 of the right straightening plate 110) of the right side first cutout portion 121 of the right straightening plate 110 are substantially at the same height as the upper end and the lower end of the range R1. Has been formed.

As shown in FIGS. 8 and 9, the left side current plate 150 is arranged between the left side ventilation hole 32 and the cooling unit 90, and is arranged so as to extend forward from the left end of the radiator 50 of the cooling unit 90. It The front end of the left side current plate 150 is located in front of the condenser 80. That is, the left side current plate 150 is arranged so as to cover the cooling unit 90 (the radiator 50, the oil cooler 60, the fuel cooler 70, and the condenser 80) from the left side.

The rear end of the first left notch 161 of the left flow plate 150 (the front position LF3 of the left flow plate 150) is formed to be located above the oil cooler 60 and the fuel cooler 70 in a side view. The rear end of the left second notch 162 of the left flow plate 150 (the front position LF2 of the left flow plate 150) is formed above the capacitor 80 in a side view. Further, the lower end of the second left cutout portion 162 of the left flow plate 150 (the height position LH1 of the left flow plate 150) is at substantially the same height as the upper ends of the condenser 80, the oil cooler 60, and the fuel cooler 70 in a side view. Has been formed.

In this way, the cutouts of the right side current plate 110 and the left side current plate 150 are formed so as to correspond to the cooling unit 90, respectively.

Next, a mode in which the air taken in from the right vent hole 31 and the left vent hole 32 is guided to the cooling unit 90 by the current plate 100 will be specifically described with reference to FIGS. 10 to 13.

Among the air taken into the inside of the bonnet 10 through the right vent hole 31 by the driving of the cooling fan 40, the air that collides with the right flow plate 110 is guided forward along the right flow plate 110. That is, the air taken into the inside of the bonnet 10 through the right side vent hole 31 is restricted from being guided from the side (right side) of the cooling unit 90 to the side of the cooling unit 90, and the right side current plate 110 controls the air. It flows to make a detour to the front.

Then, of the air guided forward, the air that has reached the right first notch 121 is guided to the cooling unit 90 side via the right first notch 121. Specifically, the air guided to the cooling unit 90 side through the right first notch 121 is guided to the front of the upper range R1 of the radiator 50. Here, no other cooler is arranged in front of the upper range R1 of the radiator 50. Therefore, in front of the upper range R1 of the radiator 50, irrespective of other coolers, from a position relatively close to the radiator 50 (specifically, not the front side position RF1 of the right flow plate 110, but the front side position RF1). Air is being directed (from position RF2).

Further, a part of the air that has reached the right side first cutout portion 121 is guided to the cooling unit 90 side via the right side corner portion 131. In this way, by supplying air from the portion where the two sides intersect in a side view (right corner 131), a certain amount of air can be collectively guided to the cooling unit 90 side. In the present embodiment, the right corner 131 is provided near the fuel cooler 70 in a side view. In this way, the right corner 131 can take in more air and efficiently cool the fuel cooler 70.

Further, of the air guided forward, the air reaching the front end of the right flow plate 110 is guided to the cooling unit 90 side via the front end. Specifically, the air guided to the cooling unit 90 side through the front end of the right flow plate 110 is guided to the front of the lower range R2 of the radiator 50. Here, another cooler (condenser 80, oil cooler 60, and fuel cooler 70) is arranged in front of the range R2 below the radiator 50. Therefore, in front of the lower range R2 of the radiator 50, air is guided from a position relatively far from the radiator 50 (specifically, not from the front position RF2 of the right flow plate 110, but from the front position RF1). doing.

As described above, the cooling unit 90 has a part where the plurality of coolers are arranged in the front-rear direction and a part where the plurality of coolers are not arranged in the front-rear direction (that is, the most front cooler is different depending on a predetermined position in front view). Air can be guided to the front of the frontmost cooler by the baffle plate 110. That is, the air can be appropriately guided to all the coolers of the cooling unit 90 via the two routes that are different from each other in the front-rear direction positions, that is, the right first cutout 121 and the front end of the right flow plate 110. Therefore, the cooling can be effectively performed in the cooler.

Further, for example, to the upper portion of the radiator 50, air that has not passed through the condenser 80, the oil cooler 60, and the fuel cooler 70 (air whose temperature has not risen) can be supplied, so that the cooling efficiency in the radiator is improved. Can be made.

Further, the air guided to the cooling unit 90 side through the right first notch 121 does not pass through the condenser 80, the oil cooler 60, and the fuel cooler 70, and therefore is excessive with respect to these condensers 80 and the like. It is possible to suppress the supply of a large amount of air. In this way, air can smoothly pass through the condenser 80 and the like.

Further, of the air guided forward, the air that has reached the right second notch 122 and the right third notch 123 is cooled by the cooling unit via the right second notch 122 and the right third notch 123. You will be guided to the 90 side. Here, as described above, the right second notch 122 and the right third notch 123 have slanted linear edges whose upper ends are located rearward and whose lower ends are located forward. That is, for example, since the air is not guided through the corners that are formed to project at a right angle in a side view, the air can be smoothly guided to the front of the cooling unit 90.

Further, the right first all-out portion 121 is open at the front and above. In this way, the right first notch 121 not only guides the lower air of the air taken in from the ventilation hole 30 to the cooling unit 90, but also the air above the right straightening plate 110. It can be easily guided to the cooling unit 90 side through the notch 121.

In addition, the non-overlapping portion 31 a of the right vent 31 when comparing the shapes of the right flow plate 110 and the right vent 31 with each other is the boundary between the right first cutout 121 and the right first portion 111 in a side view. It is formed so as to straddle the portion in the vertical direction. In this way, the air taken in from the right ventilation hole 31 can be guided to the cooling unit 90 side without being guided by the right flow plate 110 (without passing through the right flow plate 110). In this way, since the air can be guided to the cooling unit 90 side without passing through the right side current plate 110, the air is guided to the central side in the plan view of the cooling unit 90 over the entire vertical direction of the cooling unit 90. It can be done easily.

As described above, the air taken into the bonnet 10 by the cooling fan 40 is easily guided to the cooling unit 90 side from the right cutout portion 120 (that is, the portion having a low intake resistance) of the right flow plate 110. That is, all the air taken into the bonnet 10 by the cooling fan 40 can be suppressed from passing through the condenser 80, the oil cooler 60, and the fuel cooler 70 (that is, the air volume passing through the condenser 80 and the like can be reduced). It is possible to reduce the intake resistance of the cooling unit 90 as a whole, and to increase the air volume generated by the cooling fan 40. In this manner, the right cutout portion 120 of the right flow plate 110 can distribute an appropriate amount of air to each cooler that constitutes the cooling unit 90.

Further, of the air taken into the inside of the bonnet 10 through the left vent 32 by the driving of the cooling fan 40, the air that has collided with the left flow plate 150 is guided forward along the left flow plate 150. ..

Then, the air guided forward is similar to the case where the air is guided forward along the right flow plate 110, and the cutout portions (the left first notch portion 161, the left second notch portion 162, the left third notch) are provided. It is guided to the cooling unit 90 side through the portion 163, the left fourth notch 164) and the front end of the left flow plate 150. It should be noted that, of the modes that are guided to the cooling unit 90 side via the left side current plate 150, description of the substantially same modes as the right side current plate 110 will be omitted.

As described above, unlike the right side current plate 110, the left side current plate 150 is formed in a stepped shape having a step that is lowered as it goes forward by the left first notch 161 and the left second notch 162. To be done. Thus, it is suitable for all the coolers of the cooling unit 90 via the three routes that are different from each other in the front-rear direction, that is, the left first notch 161, the left second notch 162, and the front end of the left flow plate 150. The air can be guided to the air, and thus the cooling can be effectively performed in the cooler.

Further, in the cooling unit 90, the condenser 80, the oil cooler 60, and the fuel cooler 70 are arranged such that the right side does not overlap in the front-rear direction and the left side overlaps in the front-rear direction in a plan view. Here, in the current plate 100, the size of the left cutout portion 160 of the left flow plate 150 as a whole is larger than the size of the right cutout portion 120 of the right flow plate 110 as a whole. In this way, it is possible to guide a relatively large amount of air to the overlapping side in the front view and a relatively small amount of air to the non-overlapping side. Then, it is possible to suppress excessive supply of air to the condenser 80, the oil cooler 60, and the fuel cooler 70 (that is, it is possible to reduce the amount of air passing through the condenser 80 and the like) and improve the cooling efficiency. ..

Hereinafter, with reference to FIGS. 4 and 14 to 25, a structure in which oil is introduced into the oil cooler 60 according to the present embodiment and a structure in which oil is drawn out from the oil cooler 60 (oil introduction/extraction structure) will be described. explain.

As shown in FIGS. 14 and 15, the oil inlet/outlet structure includes an inlet port 62 and an outlet port 63 of the oil cooler 60, an oil outward path 200, an oil return path 300, and a check valve 400.

As will be described later, in the oil outward path 200 and the oil return path 300, pipes (outgoing path pipe 210 and the like) are fixed to the joint portions (outward path first joint portion 231 and the like), but for convenience of explanation, in the drawings, The state before the said piping is fixed to a joint part is shown. Thus, in each drawing, for convenience of description, the omission or modification of the illustration of each member is appropriately performed.

The introduction port 62 of the oil cooler 60 shown in FIGS. 14 to 16 and the like is a portion into which oil is introduced into the oil cooler 60. The introduction port 62 is formed in a substantially cubic shape with its front, rear, up, down, left, and right directions. The introduction port 62 has a through hole penetrating in the left-right direction, and a screw is formed on the inner peripheral surface thereof. The introduction port 62 is provided in the lower right part of the oil cooler 60. More specifically, the introduction port 62 is fixed to the end portion of the tube 61 provided in the oil cooler 60 so as to project from the lower right portion to the right side, and communicates with the tube 61.

The outlet port 63 of the oil cooler 60 shown in FIGS. 14 to 16 and the like is a portion from which oil is led out. The lead-out port 63 is formed in a substantially cubic shape with its front, rear, upper, lower, left, and right directions. The lead-out port 63 has a through hole penetrating in the left-right direction, and a screw is formed on the inner peripheral surface thereof. The outlet port 63 is provided in the upper right portion of the oil cooler 60. More specifically, the outlet port 63 is fixed to the end portion of the tube 61 provided in the oil cooler 60 so as to project from the upper right portion to the right side, and communicates with the tube 61.

The oil outflow path 200 shown in FIG. 4, FIG. 14, FIG. 15, and FIG. 17 is one in which oil flows to the oil cooler 60. The downstream end (in the circulation direction) of the oil outward path 200 is connected to the introduction port 62 of the oil cooler 60. The upstream end (in the circulation direction) of the oil outward path 200 is connected to the control unit of the power steering mechanism (not shown). Further, a lower portion of the check valve 400 is connected to a connection portion (hereinafter, referred to as “first connection portion 510”) of the oil outward passage 200 with the introduction port 62. The oil outward path 200 includes an outward path pipe 210 and an outward path first joint portion 231.

The outward pipe 210 is a portion of the oil outward passage 200 where the oil flows to the outward first joint portion 231. The outward pipe 210 is arranged substantially to the right of the machine body frame 2 and is formed so as to extend in the front-rear direction. The outward pipe 210 is formed by a metal pipe (for example, a copper pipe) or the like between the outward pipe 210 and a block joint 250 described later. A downstream end (front end) of the outward pipe 210 is formed so as to extend upward from below via the support base 21, and is inserted into the outward first joint portion 231.

The outward path first joint portion 231 is for connecting the outward path pipe 210 to the introduction port 62 of the oil cooler 60. The outward first joint portion 231 includes a joint body portion 235, a joint ring portion 236, and a joint nut portion 237.

The joint main body portion 235 constitutes a part of the first connection portion 510 (connection portion with the introduction port 62). The joint body portion 235 includes a joint body upper portion 241 and a joint body lower portion 242.

The joint body upper portion 241 constitutes an upper portion of the joint body portion 235. The joint main body upper part 241 is formed in a substantially rectangular parallelepiped shape with its front, rear, upper, lower, left and right directions. A joint body through hole 244 is formed in the joint body upper portion 241 so as to penetrate in the left-right direction.

The joint main body lower part 242 constitutes a lower part of the joint main body part 235. The joint main body lower portion 242 is formed in a substantially tubular shape with its tubular center oriented in the vertical direction. The joint body lower portion 242 is formed to extend downward from the bottom surface of the joint body upper portion 241. The joint body lower portion 242 is formed integrally with the joint body upper portion 241. The inside of the joint body lower portion 242 is communicated with the joint body through hole 244 of the joint body upper portion 241. A screw is formed on the outer peripheral surface of the joint body lower portion 242. A step portion 245 with its surface facing downward is formed in a middle portion of the inner peripheral surface of the joint main body lower portion 242 in the vertical direction. Of the inner peripheral surface of the joint main body lower portion 242, the portion below the step portion 245 is formed as an inclined surface whose inner diameter gradually increases as it goes downward.

The joint ring portion 236 is for fixing the outward pipe 210 to the joint main body portion 235 together with the joint nut portion 237 described later. The joint ring portion 236 is formed in a substantially tubular shape with its tubular center oriented vertically. The outer peripheral surface of the joint ring portion 236 is formed as an inclined surface whose outer diameter gradually decreases as it goes upward.

The joint nut portion 237 is for fixing the outward pipe 210 to the joint main body portion 235 together with the joint ring portion 236. The joint nut portion 237 is formed in a substantially hexagonal nut shape with its axis centered in the vertical direction. A screw is formed on the inner peripheral surface of the joint nut portion 237. A bottom surface portion 246 having a smaller inner diameter than the other portions in the vertical direction is formed at the lower end portion of the joint nut portion 237. In this way, the joint nut portion 237 is formed in a bottomed tubular shape with a part of the bottom surface opened.

In the outward first joint portion 231 having the above-described configuration, the outward pipe 210 is fixed to the joint body portion 235 by the joint ring portion 236 and the joint nut portion 237. Hereinafter, a specific mode in which the outward pipe 210 is fixed to the joint body 235 will be described.

First, the outward pipe 210 is inserted into the joint main body portion 235 with the joint nut portion 237 and the joint ring portion 236 inserted therethrough. The tip of the outward pipe 210 is brought into contact with a step portion 245 formed inside the joint body portion 235 in the vertical direction. As a result, the upward relative movement of the outward pipe 210 with respect to the joint body 235 is restricted.

In this state, the outward pipe 210 is not fixed to the joint body 235. Therefore, the outward pipe 210 is in a state of being movable relative to the joint body portion 235 (except above as described above). Specifically, the outward pipe 210 is relatively movable downward with respect to the joint body 235. Further, the outward pipe 210 is rotatable (movable) with respect to the joint body 235 around the axis of the outward pipe 210.

From this state, the joint nut portion 237 is moved upward, and the inner peripheral surface of the joint nut portion 237 and the joint body lower portion 242 of the joint body portion 235 are screwed together. Thus, when the joint nut portion 237 is screwed and further moved upward, the bottom surface portion 246 of the joint nut portion 237 comes into contact with the joint ring portion 236 from below and pushes the joint ring portion 236 upward from below. When the joint ring portion 236 is pushed upward, the slant surface of the joint body lower portion 242 of the joint body portion 235 and the slant surface of the joint ring portion 236 are slid to be deformed so as to gradually reduce the diameter. It

If the inner peripheral surface of the joint ring portion 236 is deformed so as to reduce its diameter, it will bite into the outer peripheral surface of the outward pipe 210. The inner peripheral surface of the joint ring portion 236 cuts into the outer peripheral surface of the outward pipe 210, and the screwing of the joint nut portion 237 is completed. Thus, when the inner peripheral surface of the joint ring portion 236 digs into the outer peripheral surface of the outward pipe 210, the relative movement of the outward pipe 210 with respect to the joint main body portion 235 not only in the upward direction but also in the downward direction and around the axis. Is regulated (see FIG. 17B). In this manner, the outward pipe 210 is fixed to the joint body 235.

The oil return path 300 shown in FIG. 4, FIG. 14 to FIG. 16 and the like is one in which oil flows from the oil cooler 60. The upstream end of the oil return path 300 is connected to the outlet port 63 of the oil cooler 60. The downstream end of the oil return path 300 is connected to the speed change mechanism housed in the transmission case 6. An upper portion of the check valve 400 is connected to a connection portion (hereinafter, referred to as “second connection portion 520”) of the oil return path 300 with the outlet port 63. The oil return path 300 includes a return path pipe 310 and a return path joint portion 331.

The return pipe 310 is a portion of the oil return passage 300 where the oil flows from the return joint 331. As shown in FIG. 4, the upstream end (front end) of the return pipe 310 is formed to extend downward from the inside of the return joint 331 and bend below the support base 21 to extend rearward. To be done. The return pipe 310 is arranged substantially to the right of the machine body frame 2 and is formed so as to extend in the front-rear direction. The return pipe 310 is formed by a metal pipe (for example, a copper pipe).

The return joint 331 is for connecting the return pipe 310 to the outlet port 63 of the oil cooler 60.

The return path joint portion 331 constitutes a part of the second connection portion 520 (connection portion with the lead-out port 63). The return joint section 331 includes a joint upper portion 341 formed at the upper end portion, and a joint lower portion 343 extending downward from the joint upper portion 341.

The joint upper part 341 is formed to have a flat surface on the right side and the left side. A joint body through hole 345 that penetrates in the left-right direction is formed in the joint upper portion 341 (see FIG. 21 ).

The joint lower portion 343 is formed by a metal pipe. The joint lower portion 343 is elongated in the vertical direction and is formed in a substantially pipe shape bent at a midway portion in the vertical direction. More specifically, the joint lower portion 343 has a portion that extends straight downward from the lower surface of the joint upper portion 341, a portion that extends linearly downward from the portion, and a portion that extends linearly downward from the portion. And are formed by. Thus, the joint lower portion 343 is formed so as to bypass the outward first joint portion 231 of the adjacent outward pipe 210.

A predetermined tubular member is arranged at the lower end of the joint lower portion 343. Then, for the tubular member, the joint ring portion 336 and the joint nut portion 337 configured similarly to the joint ring portion 236 and the joint nut portion 237 of the outward pipe 210 are used, and the return pipe 310 and the return joint portion 331 are used. And are connected.

The check valve 400 shown in FIG. 14 to FIG. 20 bypasses the oil flowing to the oil cooler 60 without introducing the oil into the introduction port 62 of the oil cooler 60 when the oil pressure thereof becomes higher than a predetermined oil pressure. It is for. The check valve 400 is formed in a longitudinal shape along the vertical direction. The check valve 400 includes a plurality of substantially cylindrical members that allow oil to flow. Specifically, as shown in FIGS. 18 to 20, the check valve 400 includes a lower member 410, an upper member 420, and an intermediate member 430. Further, the check valve 400 includes, as members provided inside the intermediate member 430, an upper O-ring 451, a lower O-ring 452, a retaining ring 453, a restricting cylinder portion 454, a valve body 455, and a spring 456. It is equipped with.

The lower member 410 constitutes a lower portion (lower side) of the check valve 400. The lower member 410 includes a lower head portion 411 and a lower tubular portion 412.

The lower head portion 411 constitutes a lower portion of the lower member 410. The lower head 411 is formed in a substantially rectangular parallelepiped shape with its front, back, upper, lower, left, and right directions. The lower head 411 has a lower head through hole 414 penetrating in the left-right direction. The lower head 411 is connected to the first connecting portion 510, as will be described later.

The lower cylinder portion 412 constitutes the upper portion of the lower member 410. The lower tubular portion 412 is formed in a substantially tubular shape with its tubular center oriented in the vertical direction. The lower cylinder portion 412 is formed so as to extend upward from the upper surface of the lower head portion 411. The lower cylinder portion 412 is formed integrally with the lower head portion 411. The inside of the lower tubular portion 412 is communicated with the lower head through hole 414 of the lower member head. The lower cylinder portion 412 is formed with a lower cylinder portion reduced diameter portion 415 whose outer diameter is reduced in a predetermined vertical range including the upper end.

The upper member 420 constitutes an upper portion (upper side) of the check valve 400. The upper member 420 includes an upper head portion 421 and an upper tubular portion 422.

The upper head 421 constitutes the upper part of the upper member 420. The upper head 421 is formed in a substantially rectangular parallelepiped shape with its front, back, upper, lower, left, and right directions. An upper head through hole 424 is formed in the upper head 421 so as to penetrate in the left-right direction. The upper head 421 is connected to the second connecting portion 520 as described later.

The upper cylinder portion 422 constitutes a lower portion of the upper member 420. The upper tubular portion 422 is formed in a substantially tubular shape with its tubular center oriented in the vertical direction. The upper cylinder portion 422 is formed so as to extend downward from the lower surface of the upper head portion 421. The upper cylinder portion 422 is formed integrally with the upper head portion 421. The inner side of the upper cylindrical portion 422 is communicated with the upper head through hole 424 of the upper head 421. The upper cylinder part 422 is formed with an upper cylinder part reduced diameter part 425 whose outer diameter is reduced over a predetermined range in the vertical direction including the lower end.

The intermediate member 430 is provided between the lower member 410 and the upper member 420. The intermediate member 430 is connected to the lower member 410 and the upper member 420, respectively. The intermediate member 430 is formed in a substantially tubular shape with its tubular center oriented in the vertical direction. The intermediate member 430 includes an intermediate through hole 431.

The intermediate through hole 431 is a hole that penetrates the intermediate member 430 in the vertical direction. The intermediate through hole 431 is formed so as to connect the upper surface and the lower surface of the intermediate member 430. The upper tubular portion reduced diameter portion 425 of the upper member 420 is inserted into the upper end portion of the intermediate through hole 431. Further, the lower cylindrical portion reduced diameter portion 415 of the lower member 410 is inserted into the lower end portion of the intermediate through hole 431. In this way, the intermediate member 430 is formed so as to overlap the upper member 420 and the lower member 410 (members adjacent to each other) at the upper end and the lower end in the vertical direction (longitudinal direction).

In addition, as shown in FIG. 19, the intermediate through hole 431 includes an intermediate reduced diameter portion 432, an intermediate first recess 433, an intermediate second recess 434, and an intermediate third recess 435.

The intermediate reduced diameter portion 432 is formed slightly below the central portion in the vertical direction of the intermediate through hole 431. The intermediate reduced diameter portion 432 is formed to have a smaller inner diameter than the other portions over a predetermined range in the vertical direction. The intermediate reduced diameter portion 432 is configured as a so-called valve seat so that it can come into contact with a valve body 455 described later.

The intermediate first recess 433 is formed near the upper end of the intermediate through hole 431. The intermediate first recess 433 is formed such that the inner peripheral surface of the intermediate through hole 431 is recessed radially outward.

The second intermediate recess 434 is formed near the lower end of the intermediate through hole 431. The second intermediate recess 434 is formed such that the inner peripheral surface of the intermediate through hole 431 is recessed radially outward.

The third intermediate recess 435 is formed slightly above the center of the intermediate through hole 431 in the vertical direction. In other words, the intermediate third recess 435 is formed between the intermediate reduced diameter portion 432 and the intermediate first recess 433. The intermediate third recess 435 is formed such that the inner peripheral surface of the intermediate through hole 431 is recessed radially outward.

The upper O-ring 451 has an annular shape in plan view and is elastically deformable. The upper O-ring 451 is fitted into the intermediate first recess 433 of the intermediate through hole 431. The upper O-ring 451 is provided in a compressed state (elastically deformed state) between the inner peripheral surface of the intermediate through hole 431 and the outer peripheral surface of the upper tubular portion reduced diameter portion 425 of the upper member 420. In this way, the upper O-ring 451 closes the space between the intermediate through hole 431 and the upper cylindrical portion reduced diameter portion 425, and regulates the communication between them.

The lower O-ring 452 has an annular shape and is elastically deformable. The lower O-ring 452 is fitted in the intermediate second recess 434 of the intermediate through hole 431. The lower O-ring 452 is provided in a compressed state (elastically deformed state) between the inner peripheral surface of the intermediate through hole 431 and the outer peripheral surface of the lower tubular portion reduced diameter portion 415 of the lower member 410. In this way, the lower O-ring 452 closes the space between the intermediate through hole 431 and the lower cylindrical portion reduced diameter portion 415, and regulates the communication therebetween.

The retaining ring 453 has a substantially C-shaped shape in a plan view. The retaining ring 453 is fitted into the intermediate third recess 435 of the intermediate through hole 431.

The restriction tube portion 454 is formed in a substantially tube shape with its tube center oriented in the vertical direction. The upper end of the restricting cylinder portion 454 is formed in a flange shape extending inward in the radial direction. The restriction tube portion 454 is housed inside the intermediate through hole 431. A retaining ring 453 is arranged above the restricting cylinder portion 454, and the upward movement of the restricting cylinder portion 454 is restricted.

The valve body 455 is formed in a substantially tubular shape (bottomed tubular shape) with its tubular center oriented vertically. Specifically, inside the valve body 455, a valve body through hole 459 that connects the outer peripheral surface and the upper surface of the valve body 455 is formed. Further, the lower surface of the valve body 455 is formed in a bulging shape such that the radial center portion bulges downward. The valve body 455 is housed inside the intermediate through hole 431.

The spring 456 is a compression spring formed by forming a metal wire into a spiral shape (coil shape). The spring 456 is arranged between the restricting tubular portion 454 (more specifically, a flange-like portion at the upper end of the restricting tubular portion 454) and the valve element 455 in a state of being compressed with the expansion/contraction direction in the vertical direction. It In this way, the spring 456 urges the valve element 455 in the direction away from the restriction tube portion 454 (the upward movement of which is restricted), that is, in the downward direction.

With the above-described configuration, in the check valve 400, when the valve body 455 is brought into contact with the intermediate reduced diameter portion 432 (valve seat) by the urging force of the spring 456, the intermediate member 430 moves in the vertical direction at the intermediate portion in the vertical direction. The communication is restricted, and the state where the oil flow from the lower member 410 side to the upper member 420 side is prohibited (hereinafter referred to as “closed state”) is set.

Further, in the closed state, when the oil pressure of the oil on the lower member 410 side becomes higher than a predetermined oil pressure, more specifically, when it becomes high enough to resist the biasing force of the spring 456, it is shown in FIG. Thus, the valve body 455 is pushed upward by the oil. In this way, when the valve body 455 is pushed upward, the valve body 455 separates from the intermediate reduced diameter portion 432 (valve seat), so that the intermediate portion in the vertical direction of the intermediate member 430 communicates with the vertical direction. As a result, the check valve 400 enters a state in which the oil is allowed to flow from the lower member 410 side to the upper member 420 side (hereinafter, referred to as “open state”).

In the check valve 400, the upper O-ring 451, the lower O-ring 452, the retaining ring 453, the restricting cylinder portion 454, the valve body 455, the spring 456, and the intermediate reduced diameter portion 432 (valve seat) have a plurality of substantially cylindrical shapes. Of the members (the lower member 410, the upper member 420, and the intermediate member 430), the intermediate member 430 is arranged. As a result, the main components of the check valve 400 are integrated into one member (the intermediate member 430), so that the time and effort required for assembly can be reduced, and the configuration of the check valve 400 as a whole can be simplified. ..

Hereinafter, the configuration of the first connection portion 510 will be described in detail with reference to FIGS. 14 to 16, 21 and 22.

The first connection portion 510 is a portion where the oil outward path 200 and the introduction port 62 of the oil cooler 60 are connected as described above, and the lower portion (lower member 410) of the check valve 400 is also connected similarly. In the first connection portion 510, the oil outward path 200, the introduction port 62 of the oil cooler 60, and the lower member 410 of the check valve 400 are connected using the first bolt 511.

The first bolt 511 shown in FIGS. 21 and 22 is a banjo bolt. The first bolt 511 includes a first head portion 512, a first shaft portion 513, a first shaft hole 514, a first right side through hole 515, and a first left side through hole 516.

The first head 512 is a hexagonal portion. The first shaft portion 513 is a portion formed so as to extend leftward from the first head portion 512. A screw is formed on the outer peripheral surface of the first shaft portion 513. The first shaft hole 514 is a hole that extends from the vicinity of the first head 512 toward the tip side (left side) and is opened at the tip inside the first shaft portion 513. The first right through hole 515 is a hole formed in the vicinity of the first head 512 of the first shaft portion 513 so as to penetrate in the front-rear direction (radial direction). Further, the first left-side through hole 516 is a hole formed so as to penetrate in the front-rear direction (radial direction) in the left-right central portion of the first shaft portion 513. The first shaft hole 514, the first right side through hole 515, and the first left side through hole 516 communicate with each other.

In the first connection portion 510, the first bolt 511 is inserted from the right side to the left side through the joint body through hole 244 of the oil outward path 200 and the lower head side through hole 414 of the check valve 400, and The tip of the bolt 511 is screwed into the introduction port 62 of the oil cooler 60. Note that, as shown in FIG. 22, between the first bolt 511 and the outward first joint portion 231 of the outward pipe 210, between the outward first joint portion 231 of the oil outward passage 200 and the lower member 410 of the check valve 400. A washer 531 is arranged between the lower member 410 of the check valve 400 and the introduction port 62.

The first right-side through hole 515 of the first bolt 511 is arranged inside the joint main body through hole 244 of the outward first joint portion 231. The first left side through hole 516 of the first bolt 511 is arranged inside the lower head through hole 414 of the lower member 410 of the check valve 400.

Thus, in the first connection portion 510, the oil outward path 200, the lower portion (lower member 410) of the check valve 400, and the introduction port 62 of the oil cooler 60 are connected to each other via the first bolt 511. It

As described above, in the first connection portion 510, the first bolt 511 is inserted into the joint body through hole 244 of the oil outward path 200 and the lower head through hole 414 of the check valve 400 from the first bolt 511. By screwing the bolt 511 into the introduction port 62, the oil outward path 200, the check valve 400, and the introduction port 62 are fixed to each other.

That is, before the first bolt 511 is screwed, for example, the oil outward path 200 is provided so as to be swingable in the front-rear direction via the first bolt 511. Further, in the oil outward passage 200, as long as the outward passage pipe 210 is not fixed to the joint main body portion 235, the outward passage pipe 210 is provided rotatably around the axis with respect to the joint main body portion 235 as described above. In this way, at the time of assembly, it is possible to perform a plurality of types of movement (swing in the front-rear direction or rotation around the axis) with respect to the outward pipe 210, so that it is possible to improve assemblability and workability, and The stress at the time of mounting can be eliminated.

Further, the oil outward path 200 is arranged so as to extend downward from the first connection portion 510. That is, the lower end portion of the oil outward passage 200 is arranged such that the longitudinal direction thereof is oriented in the vertical direction and extends downward from the check valve 400. As described above, since a plurality of long members are arranged on the right side of the oil cooler 60 so as to be substantially continuous in the vertical direction, the space on the right side of the oil cooler 60 is effectively used and the space is saved. be able to.

Hereinafter, the configuration of the second connecting portion 520 will be described in detail with reference to FIGS. 14 to 16, 21 and 22.

The second connection portion 520 is a portion where the oil return path 300 and the outlet port 63 of the oil cooler 60 are connected as described above, and the upper portion (upper member 420) of the check valve 400 is similarly connected. At the second connection portion 520, the oil return path 300, the outlet port 63 of the oil cooler 60, and the upper member 420 of the check valve 400 are connected using the second bolt 521.

The second bolt 521 has the same configuration as the first bolt 511. Specifically, the second head portion 522 of the second bolt 521, the second shaft portion 523, the second shaft hole 524, the second right side through hole 525, and the second left side through hole 526 are respectively It is a member corresponding to the first head portion 512 of the one bolt 511, the first shaft portion 513, the first shaft hole 514, the first right side through hole 515, and the first left side through hole 516.

In the second connecting portion 520, the second bolt 521 is inserted from the right side to the left side through the joint body through hole 345 of the oil return path 300 and the upper head side through hole 424 of the check valve 400, and at the same time, the second bolt 521. The tip of 521 is screwed into the outlet port 63 of the oil cooler 60. As shown in FIG. 22, between the second bolt 521 and the return joint 331 of the oil return passage 300, between the return joint 331 of the oil return passage 300 and the upper member 420 of the check valve 400, and between the check valve 400 and the check valve 400. Washers 531 are arranged between the upper member 420 and the outlet port 63, respectively.

Further, the second right-side through hole 525 of the second bolt 521 is arranged inside the joint upper portion 341 of the oil return path 300. Further, the second left side through hole 526 of the first bolt 511 is arranged inside the upper member 420 of the check valve 400.

Thus, in the second connecting portion 520, the oil return path 300, the upper portion (upper member 420) of the check valve 400, and the outlet port 63 of the oil cooler 60 are connected to each other via the second bolt 521. ..

As described above, the check valve 400 is arranged with the first connecting portion 510 and the second connecting portion 520 with the longitudinal direction thereof oriented in the vertical direction. Further, as shown in FIG. 16, the check valve 400 is arranged so as to be the same as the oil cooler 60 in the front-rear direction position. That is, the check valve 400 is arranged so as to substantially overlap the oil cooler 60 in a side view and not to protrude to the front or the rear of the oil cooler 60. As a result, the space on the right side of the oil cooler 60 can be effectively used and the space can be saved. Further, since the check valve 400 can be arranged near the oil cooler 60, the response speed of the check valve 400 can be improved.

Further, at the time of assembly, the check valve 400 can swing in the front-rear direction via the first bolt 511 of the first connecting portion 510 before the second bolt 521 is inserted through the second connecting portion 520. It is provided. Further, the check valve 400 is provided so as to be swingable in the front-rear direction via the second bolt 521 of the second connecting portion 520 before the first bolt 511 is inserted through the first connecting portion 510. As described above, when the check valve 400 is assembled, even if one of the first bolt 511 and the second bolt 521 is inserted first, if the other is not inserted, the check valve 400 is in the front-rear direction. Since it can swing freely, it is possible to improve the assemblability and workability.

Further, when the check valve 400 is assembled, the vertical positions of the upper end and the lower end of the check valve 400 are determined according to the first connecting portion 510 and the second connecting portion 520. Therefore, it seems that relatively precise accuracy is required for the vertical position of the upper and lower ends of the check valve 400 (that is, the length of the check valve 400 in the longitudinal direction).

However, as described above, in the check valve 400, the intermediate member 430 is formed so as to overlap the upper member 420 and the lower member 410 (members adjacent to each other) at the upper and lower ends in the vertical position. .. Further, the intermediate member 430, the upper member 420, and the lower member 410 are not fixed to each other with, for example, screws (fixing means). That is, since the intermediate member 430 and the upper member 420 and the lower member 410 are configured to be movable relative to each other via the upper O-ring 451 and the lower O-ring 452, the length of the check valve 400 in the longitudinal direction. (Full length) can be changed arbitrarily.

Specifically, as shown in FIG. 23, for example, when it is desired to increase the total length of the check valve 400, the upper member 420 and the lower member 410 are pulled in the direction of separating from the intermediate member 430. As a result, the upper member 420 and the lower member 410 move upward and downward, respectively, while sliding on the upper O-ring 451 and the lower O-ring 452 of the intermediate member 430, so that the entire length of the check valve 400 is changed to be long. It Further, for example, when it is desired to shorten the entire length of the check valve 400, the upper member 420 and the lower member 410 are pushed in the direction of approaching the intermediate member 430. Accordingly, the upper member 420 and the lower member 410 move downward and upward while sliding with the upper O-ring 451 and the lower O-ring 452 of the intermediate member 430, respectively, and the total length of the check valve 400 is changed to be short. It

Thus, when the check valve 400 is assembled as described above, the vertical positions of the upper end and the lower end of the check valve 400 are determined according to the first connecting portion 510 and the second connecting portion 520, but the total length of the check valve 400 is Since it can be arbitrarily changed, the assembling property and the workability can be improved.

Hereinafter, with reference to FIGS. 24 and 25, a description will be given of an aspect of oil circulation in the oil introducing/extracting structure configured as described above.

First, as shown in FIG. 24, the check valve 400 is assumed to be in a closed state. In such a case, the oil flowing through the oil outward passage 200 is introduced from the outward passage first joint portion 231 of the outward passage pipe 210 into the first shaft hole 514 through the first right side through hole 515 of the first bolt 511. It The oil introduced into the first shaft hole 514 flows through the first shaft hole 514 toward the tip side. Then, it is introduced into the introduction port 62 of the oil cooler 60 from the opening at the tip of the first bolt 511.

Further, the oil led out from the outlet port 63 of the oil cooler 60 is introduced into the second shaft hole 524 through the opening at the tip of the second bolt 521. The oil introduced into the second shaft hole 524 flows through the second shaft hole 524 toward the second head 522 side. Then, the oil is introduced into the oil return path 300 through the second right side through hole 525.

Here, focusing on the oil flowing to the introduction port 62 of the oil cooler 60, the first shaft hole 514 of the first bolt 511 is communicated with the lower member 410 of the check valve 400 via the first left-side through hole 516. There is. However, since the check valve 400 is in the closed state and the oil is prohibited from flowing from the lower member 410 side to the upper member 420 side as described above, the oil flows through the first shaft hole 514 of the first bolt 511. The oil does not flow to the upper member 420 side and is entirely introduced into the oil cooler 60.

On the other hand, when the hydraulic pressure of the oil on the lower member 410 side of the check valve 400 becomes higher than a predetermined hydraulic pressure, the valve element 455 is pushed upward, and the check valve 400 is opened from the closed state as shown in FIG. It becomes a state. In this way, when the check valve 400 is opened, the flow of oil from the lower member 410 side to the upper member 420 side is allowed.

In such a case, a part of the oil flowing through the first shaft hole 514 of the first bolt 511 is introduced into the lower member 410 of the check valve 400 through the first left-side through hole 516 and the upper member. It flows to the 420 side. The oil flowing to the upper member 420 is introduced into the second shaft hole 524 through the second left side through hole 526 of the second bolt 521. Then, the oil introduced into the second shaft hole 524 flows through the second shaft hole 524 toward the second head 522 side. Then, the oil is introduced into the oil return path 300 through the second right side through hole 525.

As described above, in the oil introduction/extraction structure, by using the check valve 400, the oil is not introduced into the introduction port 62 of the oil cooler 60 in accordance with the oil pressure of the oil on the lower member 410 side of the check valve 400. Can be diverted. In this way, it is possible to prevent the check valve 400 from applying an excessive pressure to the oil cooler 60, and to prevent problems such as damage to the oil cooler 60 from occurring.

Hereinafter, the configuration of the block joint 250 according to the present embodiment will be described in detail with reference to FIGS. 3 and 26 to 31.

As described above, the block joint 250 is provided in the middle of the oil outward path 200 that connects the oil cooler 60 and the control unit of the power steering mechanism. The block joint 250 shown in FIGS. 26 and 27 includes a block body 251, a first block opening 252, a second block opening 253, and a block through hole 254.

The block body 251 is a main structure of the block joint 250. The block body 251 is formed of a substantially hexahedron (substantially polyhedron). The block body portion 251 has an upper surface 261 that faces generally upward, a lower surface 262 that faces generally downward, a left surface 263 that faces generally left, and a right surface 264 that faces generally right. And a front surface 265 having a front surface and a rear surface 266 having a rear surface. The left surface 263 and the right surface 264 are formed in a substantially square shape. Moreover, the upper surface 261, the lower surface 262, the front surface 265, and the rear surface 266 are formed in a substantially rectangular shape.

The first block opening 252 is an opening formed in the front surface 265 of the block body 251. The first block opening 252 has a perfect circular shape. The first block opening 252 is formed in a portion of the front surface 265 near the lower surface 262. The diameter of the first block opening 252 is approximately half the length of the front surface 265 in the longitudinal direction (the length in the direction in which the upper surface 261 and the lower surface 262 face each other), and the length of the front surface 265 in the lateral direction (right surface). 264 and the left surface 263 are formed to have a length of about 3/4).

The second block opening 253 is an opening formed in the upper surface 261 of the block body 251. That is, the second block opening 253 is formed on a surface adjacent to the front surface 265 where the first block opening 252 is formed. The second block opening portion 253 has a perfect circular shape. The second block opening 253 is formed in the upper surface 261 in the vicinity of the right surface 264 and the rear surface 266. The diameter of the second block opening 253 is approximately half the length of the upper surface 261 in the longitudinal direction (the length in the direction in which the front surface 265 and the rear surface 266 face each other), and the length of the upper surface 261 in the lateral direction (right surface). 264 and the left surface 263 are formed to have a length of about 3/4).

The block through hole 254 is a hole formed inside the block body 251. The block through hole 254 is formed so as to connect the first block opening 252 and the second block opening 253. More specifically, the block through hole 254 is formed so as to extend linearly from the first block opening 252 to the rear surface 266 side and to extend linearly from the second block opening 253 to the lower surface 262 side. And the portion formed in the cross section are formed by intersecting each other. In this way, the block through hole 254 is formed in a substantially L shape as a whole. Further, in the block through hole 254, screws are formed on the inner peripheral surfaces near the first block opening 252 and the second block opening 253, respectively.

The block joint 250 configured as described above is fixed to the flywheel housing 4 via the stay 270.

First, the configuration of the flywheel housing 4 will be described with reference to FIGS. 3, 28 and 30.

The flywheel housing 4 covers a flywheel (not shown). The flywheel housing 4 is a hollow, substantially disk-shaped body having a thickness in the front-rear direction, and is formed relatively large so as to extend in the left-right direction of the vehicle body. The flywheel housing 4 is formed in a substantially circular shape except for the lower end portion when viewed from the front. The flywheel housing 4 includes a mount 23 to which the bonnet support member 24 is mounted. The bonnet support member 24 is formed so as to rotatably support the rear part of the bonnet 10 and to stand upright from the mount 23.

The mounts 23 are provided on the left side and the right side of the flywheel housing 4, respectively. In the following, of the left and right mounts 23, the description will be given focusing on the right mount 23, and the description of the left mount 23 will be omitted. Further, hereinafter, the right-side mounting base 23 is simply referred to as “mounting base 23” unless otherwise specified.

The mount 23 is formed on the upper right portion of the flywheel housing 4. More specifically, the mounting base 23 is formed on the outer peripheral portion of the flywheel housing 4 at a midway portion in the circumferential direction between the upper end 4a and the right end 4b. The mount 23 is formed in a convex shape that is convex upward. Thus, the mount 23 is formed so as to project upward from the upper right portion of the flywheel housing 4. A substantially horizontal surface is formed on the upper end (the upper surface of the convex shape) of the mounting base 23. The height of the upper end of the mount 23 is lower than the upper end 4 a of the flywheel housing 4.

As described above, the entire mount 23 includes the first virtual line L1 extending rightward from the upper end 4a of the flywheel housing 4 and the second virtual line extending upward from the right end 4b of the flywheel housing 4 in a front view. It is arranged in a region surrounded by L2. That is, the mount 23 is formed so as to be located inside the flywheel housing 4 in the vertical and horizontal directions.

Next, the configuration of the stay 270 and the configuration in which the block joint 250 is fixed to the flywheel housing 4 via the stay 270 will be described.

The stay 270 shown in FIGS. 26 and 27 is a member for fixing the block joint 250 to the flywheel housing 4. The stay 270 is formed in a substantially elongated plate shape made of metal. The stay 270 includes a stay fixing portion 271, a bending portion 272, and a joint fixing portion 273.

The stay fixing portion 271 is a portion for fixing the stay 270 to the flywheel housing 4. As shown in FIGS. 28 and 31, the stay fixing portion 271 is arranged so as to be in contact with the rear end portion of the upper end of the mounting base 23 with the plate surface thereof oriented in the vertical direction. The stay fixing portion 271 is fixed to the upper end of the mounting base 23 via a bolt.

The bent portion 272 is a portion where the stay 270 is bent. Due to the bent portion 272, the portion of the stay 270 other than the stay fixing portion 271 is formed so that the plate surface faces the upper right and the lower left, and extends from the stay fixing portion 271 to the lower right.

The joint fixing portion 273 is a portion for fixing the block joint 250. The joint fixing portion 273 is formed at the lower right end of the stay 270. The left side surface 263 of the block joint 250 is arranged in contact with the joint fixing portion 273. In this way, the block joint 250 is fixed to the joint fixing portion 273 by welding or the like.

In this way, the block joint 250 is fixed while being separated from the flywheel housing 4 via the stay 270. The vertical position of the block joint 250 is formed to be substantially the same as the bottom surface of the cabin 12 (see FIG. 30).

As shown in FIG. 31, the block joint 250 fixed as described above has the first imaginary line L1 extending rightward from the upper end 4a of the flywheel housing 4 in a front view, like the entire mounting base 23, The flywheel housing 4 is arranged in a region surrounded by the second imaginary line L2 extending upward from the right end 4b. That is, the block joint 250 is formed so as to be located inside the flywheel housing 4 in the vertical and horizontal directions.

As described above, the block joint 250 is provided in the middle of the oil outward path 200 that connects the oil cooler 60 and the control unit of the power steering mechanism. More specifically, the block joint 250 includes a forward path upstream side piping 211 on the control unit side (upstream side) and an oil cooler 60 side (downstream side) of the forward path piping 210 which is a portion of the oil forward path 200 through which oil flows. It is provided between the downstream side downstream side pipe 212 on the side), and these pipes are connected in a state of communicating with each other.

The outgoing upstream pipe 211 is a flexible rubber pipe. The upstream upstream pipe 211 is formed to extend from above the flywheel housing 4 toward the flywheel housing 4 side. Then, the downstream end portion (that is, the end portion on the block joint 250 side) of the outgoing upstream pipe 211 is above the stay 270 and along the extending direction (lower right) of the stay 270 (so that it is substantially parallel). Is formed to extend. An outward second joint portion 232 is provided at the downstream end of the outward upstream pipe 211.

The outward second joint portion 232 is formed in a substantially cylindrical shape. The outward second joint portion 232 is fixed in a state where the downstream end of the outward upstream pipe 211 is inserted. A screw is formed on the outer peripheral surface of the outward second joint portion 232.

The outward path downstream side pipe 212 is a metal pipe (at least less flexible than the outward path upstream side pipe 211). A forward outward third joint portion 233 is provided at the upstream end portion of the outward downstream pipe 212 (that is, the end portion on the block joint 250 side).

The outward third joint portion 233 is formed in a substantially cylindrical shape. The outward third joint portion 233 is fixed in a state where the upstream end of the outward downstream pipe 212 is inserted. A screw is formed on the outer peripheral surface of the outward third joint portion 233.

The outward second joint portion 232 configured as described above is screwed into the second block opening portion 253 of the block joint 250. In this way, the upstream upstream pipe 211 is connected (fixed) to the block joint 250. Further, the outward third joint 233 is screwed into the first block opening 252 of the block joint 250. In this way, the outward downstream pipe 212 is connected (fixed) to the block joint 250.

As a result, the block joint 250 connects the upstream upstream pipe 211 on the upstream side and the downstream downstream pipe 212 on the downstream side in the midway portion of the oil forward passage 200 in a mutually communicating state.

In this way, the block joint 250 connects the forward path upstream side pipe 211 and the forward path downstream side pipe 212 to the surfaces (front surface 265 and upper surface 261) that are adjacent to each other in the middle of the oil outward path 200. This makes it possible to provide a predetermined angle (90 degrees in this embodiment) in the middle of the oil outward path 200 with a simple configuration.

Further, in the present embodiment, the outward path upstream side pipe 211 is a rubber tube, whereas the outward path downstream side pipe 212 is a metal pipe. As described above, since pipes having different flexibility can be easily connected via the block joint 250, the degree of freedom in design can be improved. That is, the forward path upstream side pipe 211 and the forward path downstream side pipe 212 can be appropriately selected and used according to the location where the piping is provided, the application, and the like. For example, the use of the outgoing downstream pipe 212 can improve strength, earthquake resistance, and durability. Further, by using the upstream upstream pipe 211, cost reduction and easy assembly can be achieved.

The block joint 250 is fixed to the flywheel housing 4 via a stay 270. In this way, the flywheel housing 4 having a relatively high rigidity can be used to improve the degree of freedom in design.

Further, as described above, the downstream end of the upstream upstream pipe 211 is formed above the stay 270 and extends along the extending direction of the stay 270. Thereby, space saving can be achieved. Further, by arranging the metal stay 270 along the outward path upstream side pipe 211 which is a rubber tube, the outward path upstream side pipe 211 can be protected.

The block joint 250 is fixed in a state of being separated from the flywheel housing 4 via the stay 270. That is, since the connecting portion between the upstream upstream pipe 211 and the downstream downstream pipe 212 is separated from the vehicle body including the flywheel housing 4, the upstream upstream pipe 211 and the downstream downstream pipe 212 against the vibration of the vehicle body. It is possible to reduce the influence on the connection portion (block joint 250). In particular, in this embodiment, since the stay fixing portion 271 of the stay 270 is fixed with the plate surface thereof oriented in the vertical direction, it is possible to effectively absorb the vertical vibration of the vehicle body, and the block joint 250 Can be effectively reduced.

In addition, the stay 270 is fixed to the mount 23 of the flywheel housing 4, which has a substantially horizontal surface at the upper end (convex upper surface side). In this way, the vicinity of the flywheel housing 4, which is a place that is relatively difficult to effectively use because it is a large disk-shaped member, can be effectively used. The mount 23 is a member to which the bonnet support member 24 is attached. As described above, since the block joint 250 is fixed by using the portion of the flywheel housing 4 used for other purposes, the structure can be simplified and the vicinity of the flywheel housing 4 can be effectively used. You can

Further, the block joint 250 is formed so as to be located inside the flywheel housing 4 in the vertical and horizontal directions. As a result, the vicinity of the flywheel housing 4 can be effectively and effectively utilized.

As described above, the tractor 1 (work vehicle) according to the present embodiment is
A bonnet 10 having a vent hole 30 on the left and right side,
A cooling fan 40 which is provided inside the bonnet 10 and takes in air outside the bonnet 10 through the ventilation holes 30;
A cooling unit 90 provided inside the bonnet 10 in front of the cooling fan 40 and cooling the fluid to be cooled by the air taken in by the cooling fan 40;
Notches (right side notch 120 and left side notch 160) which are provided inside the bonnet 10 between the ventilation hole 30 and the cooling unit 90 and which are substantially rectangular in a side view and whose front and upper sides are open. A pair of straightening vanes 100 (a right straightening vane 110 and a left straightening vane 150) are provided.

With such a configuration, the flow of the air taken into the inside of the bonnet 10 from the ventilation hole 30 can be suitably adjusted by the pair of straightening vanes 100 (the right straightening vane 110 and the left straightening vane 150).
Specifically, a route for guiding the air between the vent hole 30 and the straightening vane 100 (that is, the side of the cooling unit 90) after being taken in from the vent hole 30 from the front end portion of the straightening vane 100. It is possible to guide to the front of the cooling unit 90 via two routes that are different from each other in the front-rear direction, that is, a route that is guided from the cutout portion of the straightening vane.
That is, the air between the ventilation holes 30 and the flow straightening plate 100 after being taken in from the ventilation holes 30 is different in the vertical position and in the front-rear position in front of the cooling unit 90. Since it is possible to guide the cooling unit 90, it is possible to supply an appropriate amount of air as needed for the cooling unit 90. Thereby, the cooling efficiency of the cooling unit 90 can be improved.
Further, since the overall intake resistance is reduced as compared with, for example, the case where the notches (the right notch 120 and the left notch 160) are not provided, it is possible to increase the total air volume inside the bonnet 10.
Further, since the total air volume inside the bonnet 10 can be increased without increasing the rotation speed of the cooling fan 40, it is possible to suppress an increase in noise of the cooling fan 40.

In the tractor 1,
The notches (the right notch 120 and the left notch 160) are
It has a corner portion (right side corner portion 131, left side first corner portion 171, left side second corner portion 172) whose angle between two sides is approximately 90 degrees.

With such a configuration, more air can be taken into the right corner 131, for example. Accordingly, when the heat is stagnant or concentrated, or when more air is desired to flow, the right-side corner portion 131 is provided in the vicinity of the necessary portion (in the present embodiment, the fuel cooler 70), so that the air can be efficiently emitted. I can guide you.

In the tractor 1,
In the cutout portion of the pair of straightening vanes 100,
The left first all-notch portion 161 and the left left second notch portion 162 each having a step-like step descending forward are included.

With such a configuration, the airflow between the air holes 30 and the current plate 100 after being taken in from the air holes 30 is different from each other in the front-rear direction position by having a step even in the cutout portion of the air flow plate 100. It can be guided to the front of the cooling unit 90 via a plurality of routes.

In the tractor 1,
In the cutout portion of the pair of straightening vanes 100,
It includes a right side second cutout portion 122, a right side third cutout portion 124, a left side third cutout portion 163, and a left side fourth cutout portion 164 in which the corner of the mouth opened to the front is formed in a cutout shape. ..

With such a configuration, the air between the vent hole 30 and the flow straightening plate 100 after being taken in from the vent hole 30 can be guided to the front of the cooling unit 90 through the flow straightening plate 100 as smoothly as possible. it can.

In the tractor 1,
The vent hole 30 of the bonnet 10 is
A first part that overlaps with the current plate 100 in a side view, and a second part that does not overlap (non-overlap part 31a/non-overlap part 32a),
The second part is
The cutouts (the right first cutout 121, the left first cutout 161, the left second cutout 162) are provided so as to straddle the lower end in the vertical direction.

With such a configuration, the air guided to the front of the cooling unit 90 can include not only the air guided through the straightening vanes 100 but also the air guided without the straightening vanes 100.

In the tractor 1,
The cooling unit 90 is
Having a plurality of coolers whose cooling targets are different from each other,
The plurality of coolers,
The radiator 50 (first cooler) is provided in front of the radiator 50 (first cooler), and the height position of the upper end portion of the radiator 50 (first cooler) is lower than that of the radiator 50 (first cooler). Including a condenser 80, an oil cooler 60, a fuel cooler 70 (second cooler),
In the cutout portion of the pair of straightening vanes 100,
It includes a notch (a right notch 120 and a left notch 160) provided at a position spaced apart from the radiator 50 (first cooler) in the front view in a side view.

With such a configuration, the temperature of the first cooler (radiator 50) has not risen (air that has not passed through the condenser 80, the oil cooler 60, the fuel cooler 70 (second cooler)). Can be supplied.

In the tractor 1,
In the cutout portion of the pair of straightening vanes 100,
It includes a right side first cutout 121 and a left side first cutout 161 provided above the condenser 80, the oil cooler 60, and the fuel cooler 70 (second cooler) in a side view.

With this configuration, the air guided from the right first notch 121 and the left first notch 161 of the straightening vane 100 to the front of the cooling unit 90 receives the condenser 80, the oil cooler 60, the fuel cooler 70 (first Since it is not supplied to the second cooler), an excessive amount of air can be suppressed from being supplied to the second cooler.

In the tractor 1,
The second cooler is
An oil cooler 60, a fuel cooler 70 (third cooler), and a condenser 80 (fourth cooler) provided in front of the oil cooler 60, the fuel cooler 70 (third cooler),
The condenser 80, the oil cooler 60, and the fuel cooler 70 (the third cooler and the fourth cooler) are
It is provided so that one side on the left and right side does not overlap and the other side on the left and right sides overlap in front view
The cutout portions of the pair of straightening vanes 100 are
In a side view, the left cutout 160 on the other side of the left and right sides is formed larger than the right cutout 120 on the one side of the left and right sides.

With such a configuration, a relatively large amount of air is guided to the side where the condenser 80, the oil cooler 60, and the fuel cooler 70 (the third cooler and the fourth cooler) overlap in front view, A relatively small amount of air can be guided to the non-overlapping side.
In this way, it is possible to prevent excessive air from being supplied to the condenser 80, the oil cooler 60, and the fuel cooler 70 (the third cooler and the fourth cooler) and improve the cooling efficiency. it can.

The tractor 1 according to the present embodiment is an embodiment of a work vehicle.
The right cutout 120 and the left cutout 160 according to the present embodiment are one embodiment of the cutout.
Further, the right side current plate 110 and the left side current plate 150 according to the present embodiment are one embodiment of the current plate.
Further, the non-overlapping portion 31a and the non-overlapping portion 32a according to the present embodiment is an embodiment of the second portion that does not overlap.
Further, the radiator 50 according to the present embodiment is an embodiment of the first cooler.
Further, the condenser 80, the oil cooler 60, and the fuel cooler 70 according to the present embodiment are an embodiment of the second cooler.
Further, the oil cooler 60 and the fuel cooler 70 according to the present embodiment are an embodiment of the third cooler.
Further, the condenser 80 according to the present embodiment is an embodiment of the fourth cooler.
Further, the right side corner 131, the left side first corner 171, and the left side second corner 172 according to the present embodiment are one embodiment of the corners.

Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, in the present embodiment, the tractor 1 is exemplified as the work vehicle, but the present invention is not limited to such an aspect. For example, the work vehicle may be another agricultural vehicle, construction vehicle, industrial vehicle, or the like.

Further, in the present embodiment, the cooling unit 90 includes the radiator 50, the oil cooler 60, the fuel cooler 70, and the condenser 80, but the cooling unit 90 is not limited to this. Further, the arrangement configuration of the radiator 50, the oil cooler 60, the fuel cooler 70, and the condenser 80 is not limited to that according to the present embodiment, and any arrangement configuration can be adopted.

The configuration of the current plate 100 is not limited to that according to the present embodiment. For example, the right side current plate 110 and the left side current plate 150 do not have to include all the cutout portions according to the present embodiment. Further, the right side current plate 110 and the left side current plate 150 may be provided with a cutout portion different from the cutout portion according to the present embodiment.

Further, the right side current plate 110 and the left side current plate 150 may be formed such that their front ends (portions facing forward) are bent toward the inside of the vehicle body. With such a configuration, the air can be guided to the cooling unit 90 side more smoothly. Further, the right side current plate 110 and the left side current plate 150 may be positioned such that their upper ends and front ends are located in the immediate vicinity of the bonnet 10. With such a configuration, for example, when the bonnet 10 in the open state is closed, if the tip side of the bonnet 10 is closed in a state in which the bonnet 10 is inclined in the left-right direction, the inside of the bonnet 10 is closed by the right side current plate 110 and the left side current plate 150. The bonnet 10 can be guided to the correct position.

Further, in the present embodiment, the left first notch 161 and the left second notch 162 are formed in a step shape having one step, but it is also possible to have two or more steps.

Further, in the present embodiment, the right corner 131 is provided near the fuel cooler 70, but the invention is not limited to this. That is, the right corner 131 is provided in the vicinity of an arbitrary portion such as a portion where heat is stagnant or concentrated or a portion where more air is to flow, so that more air can be guided to the portion and the cooling can be efficiently performed. can do.

As described above, the tractor 1 (work vehicle) according to the present embodiment is
An oil cooler 60 that is formed in a substantially rectangular shape in a front view and that has an outlet port 63 and an inlet port 62 (connection port) on the upper and lower sides of the right side (one side in the left-right direction);
An oil outward path 200 (oil supply oil path) which is connected to the introduction port 62 (upper or lower connection port) and supplies oil to the oil cooler 60;
An oil return path 300 (oil discharge oil path) connected to the outlet port 63 (upper or lower other connection port) and discharging oil from the oil cooler 60;
A check valve 400 (valve) which is formed in a longitudinal shape and allows a flow of oil from one side in the longitudinal direction to the other side in the longitudinal direction according to the hydraulic pressure on the one side in the longitudinal direction.
Equipped with,
The check valve 400 (valve) is
The one end in the longitudinal direction is connected to a first connection portion 510 (first connection portion) between the introduction port 62 (one connection port) and the oil outward passage 200 (oil supply oil passage), and The end portion on the other side in the longitudinal direction is connected to a second connection portion 520 (second connection portion) between the outlet port 63 (the other connection port) and the oil return passage 300 (oil discharge oil passage), It is arranged so that the direction is the vertical direction.

With such a configuration, the space on the side of the oil cooler 60 can be effectively utilized and the space can be saved.

In the tractor 1 (work vehicle),
The check valve 400 (valve) is
A plurality of cylindrical members (lower member 410, intermediate member 430, and upper member 420) configured to allow oil to flow in the longitudinal direction,
The plurality of tubular members,
Having one tubular member and another tubular member adjacent to each other in the longitudinal direction,
The overlapping portions of the one tubular member and the other tubular member at the positions in the longitudinal direction,
One is inserted into the other so as to be relatively movable via a substantially annular first seal member (upper O-ring 451 and lower O-ring 452).

With such a configuration, variations in the vertical direction of the check valve 400 can be absorbed, and the assemblability and workability can be improved.

In the tractor 1 (work vehicle),
The plurality of tubular members,
A lower member 410 connected to the first connection portion 510 (first connection portion),
An upper member 420 connected to the second connection portion 520 (second connection portion),
Intermediate members 430 provided between the lower member 410 and the upper member 420 in the longitudinal direction and adjacent to each other;
Included,
One of the lower member 410 and the intermediate member 430 is inserted into the other as the one tubular member and the other tubular member,
One of the upper member 420 and the intermediate member 430 is inserted into the other as the one tubular member and the other tubular member, respectively.

With such a configuration, the intermediate member 430 can be relatively moved in the longitudinal direction with respect to the lower member 410 and the upper member 420, so that the vertical variation of the check valve 400 can be absorbed, and the assemblability and processing can be performed. It is possible to improve the sex.

In the tractor 1 (work vehicle),
The intermediate member 430 is
An intermediate reduced diameter portion 432 (valve seat) provided inside the intermediate member 430;
A valve body 455 provided inside the intermediate member 430 so as to be slidable in the longitudinal direction;
A spring 456 (biasing member) that biases the valve element toward the valve seat side against the hydraulic pressure on one side in the longitudinal direction;
Is to have.

With such a configuration, in the check valve 400 formed by combining a plurality of members, the main configuration is integrated into one member (intermediate member 430), so that the configuration of the valve as a whole can be simplified. ..

In the tractor 1 (work vehicle),
The check valve 400 is
A lower head through hole 414 (first through hole) penetrating the one end in the longitudinal direction of the check valve 400 in the left-right direction,
The first connecting portion 510 (first connecting portion) via a first bolt 511 (first fastening member) inserted through the lower head through hole 414 (first through hole) to the other side in the left-right direction. ) Is connected with.

With such a configuration, at the time of assembling, the check valve 400 can be swung in the front-rear direction around the end portion on one side in the longitudinal direction of the check valve 400, so that the assembling property and the workability can be improved.

In the tractor 1 (work vehicle),
The check valve 400 is
An upper head through hole 424 (second through hole) penetrating the other end of the check valve 400 in the longitudinal direction in the left-right direction,
The second connecting portion 520 (second connecting portion) via the second bolt 521 (second fastening member) inserted through the upper head through hole 424 (second through hole) to the other side in the left-right direction. ) Is connected with.

With such a configuration, at the time of assembling, the check valve 400 can be swung in the front-rear direction around the end portion on the other side in the longitudinal direction of the check valve 400, so that the assemblability and workability can be improved.

In the tractor 1 (work vehicle),
The upstream end portion (the end portion on the second connection portion side) of the oil return passage 300 (oil discharge oil passage) is
The upstream end (the end on the side of the second connecting portion) has its longitudinal direction oriented in the up-down direction, and is arranged so as to be adjacent to the check valve 400 (valve).

With such a configuration, the space on the side of the oil cooler 60 can be effectively utilized and the space can be saved.

In the tractor 1 (work vehicle),
The downstream end portion (end portion on the first connection portion side) of the oil outward passage 200 (oil supply oil passage) is
The longitudinal end of the downstream end (the end on the first connection portion side) is oriented in the up-down direction, and is arranged so as to extend downward from the check valve 400 (valve).

With such a configuration, the space on the side of the oil cooler 60 can be effectively utilized and the space can be saved.

In the tractor 1 (work vehicle),
At the downstream side end portion (end portion on the first connection portion side) of the oil outward passage 200 (oil supply oil passage),
A joint body portion 235 (first supply oil passage side connection portion) which is included in the first connection portion 510 and has a joint body through hole 244 (third through hole) that penetrates in the left-right direction;
A forward pipe 210 (flow passage portion) that serves as an oil flow passage,
A joint ring portion 236 and a joint nut portion 237 (fixing means) for fixing the joint main body portion 235 (first supply oil passage side connection portion) and the outward passage pipe 210 (flow passage portion);
Is provided,
The joint body portion 235 (first supply oil passage side connection portion) is
The introduction port 62 (one connection port) via the first bolt 511 (third fastening member) inserted through the joint body through hole 244 (third through hole) to the left side (the other side in the left-right direction). ), and the outward pipe 210 (flow passage portion) is connected by the joint ring portion 236 and the joint nut portion 237 (fixing means) while the forward passage pipe 210 (flow passage portion) is connected so as to be relatively movable. Is fixed.

With such a configuration, at the time of assembly, the oil outward path 200 (oil supply oil path) is swung in the front-rear direction around the first bolt 511 (third fastening member), and the joint body 235 (first Since the outward pipe 210 (flow passage portion) can be arbitrarily moved (for example, rotated around the axis) with respect to the supply oil passage side connection portion), it is possible to improve the assemblability and workability.

In the tractor 1,
The oil cooler 60 is disposed inside the bonnet 10,
It is provided in front of the engine 3.

With such a configuration, the space on the side of the oil cooler 60 can be effectively used in front of the engine 3 inside the hood 10, and the space can be saved.

The check valve 400 according to the present embodiment is an embodiment of the valve.
Further, the derivation port 63 and the introduction port 62 according to the present embodiment are one embodiment of the connection port.
The oil outward path 200 according to the present embodiment is an embodiment of the oil supply oil path.
The oil return path 300 according to the present embodiment is an embodiment of the oil discharge oil path.
The first connecting portion 510 according to this embodiment is an embodiment of the first connecting portion.
The second connecting portion 520 according to this embodiment is an embodiment of the second connecting portion.
Further, the lower member 410, the intermediate member 430, and the upper member 420 according to the present embodiment are an embodiment of a plurality of tubular members.
Further, the upper O-ring 451 and the lower O-ring 452 according to the present embodiment are an embodiment of the first seal member.
The spring 456 according to this embodiment is an embodiment of the biasing member.
The intermediate reduced diameter portion 432 according to the present embodiment is an embodiment of the valve seat.
The lower head penetration hole 414 according to the present embodiment is an embodiment of the first penetration hole.
The first bolt 511 according to the present embodiment is an embodiment of the first fastening member.
Further, the upper head through hole 424 according to the present embodiment is an embodiment of the second through hole.
The second bolt 521 according to this embodiment is an embodiment of the second fastening member.
Further, the joint body through hole 244 according to the present embodiment is an embodiment of the third through hole.
The joint body 235 according to this embodiment is an embodiment of the first supply oil passage side connecting portion.
Further, the joint ring portion 236 and the joint nut portion 237 according to this embodiment are an embodiment of the fixing means.
The first bolt 511 according to the present embodiment is an embodiment of the third fastening member.
Further, the present embodiment is one embodiment of.
Further, the present embodiment is one embodiment of.

Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, in the present embodiment, the oil cooler 60 is arranged inside the bonnet 10, but the present invention is not limited to this. Although the oil cooler 60 is arranged in front of the engine 3, the invention is not limited to this.

Further, although the check valve 400 is arranged so that the upstream side faces downward and the downstream side faces upward, it may be arranged in the opposite direction. The check valve 400 is composed of three cylindrical members, but may be two or four or more. In the check valve 400, the lower member 410 and the upper member 420 are movably connected to the intermediate member 430 via the O-rings, respectively. Alternatively, either one of them may be movably connected via the O-ring. Further, although the lower member 410 and the upper member 420 are inserted inside the intermediate member 430, respectively, the intermediate member 430 may be inserted in the lower member 410 and the upper member 420.

As described above, the tractor 1 (work vehicle) according to the present embodiment is
A downstream pipe 212 (first pipe line) through which oil (fluid) flows,
An outward flow upstream pipe 211 (second pipe line) through which the oil (fluid) flows and which is more flexible than the outward flow downstream pipe 212 (first pipe line);
A block joint 250 that connects the forward path downstream side pipe 212 (first pipeline) and the forward path upstream side pipe 211 (second pipeline);
It is equipped with.

With such a configuration, pipe lines having different flexibility can be connected via the block joint 250, so that the degree of freedom in design can be improved.
In this way, it is possible to appropriately select and use the outgoing downstream pipe 212 (first pipeline) and the upstream upstream pipe 211 (second pipeline) according to the place of installation, the application, and the like. For example, it is possible to improve strength, seismic resistance, and durability by using the outward downstream pipe 212 (first pipeline). In addition, by using the upstream upstream pipe 211 (second pipeline), cost reduction and easy assembly can be achieved.

In the tractor 1,
The block joint 250 is
It is formed by a substantially hexahedron (polyhedron),
The forward passage downstream side pipe 212 (first pipe line) is connected to the front surface 265 (a predetermined one surface),
The upstream upstream pipe 211 (second pipeline) is connected to the upper surface 261 (other surface) adjacent to the front surface 265 (predetermined one surface).

With such a configuration, it is possible to provide a predetermined angle between the outward-path downstream-side pipe 212 (first pipe line) and the outward-path upstream-side pipe 211 (second pipe line) with a simple configuration.
In addition, in the present embodiment, the block joint 250 is formed by making a hole in the block-shaped member (block body 251) from two surfaces adjacent to each other. In this way, the block joint 250 can be formed with a simple structure, so that the cost can be reduced.

In the tractor 1,
The block joint 250 is
The block joint 250 is fixed in a state of being separated from the flywheel housing 4 (fixed member) to which the block joint 250 is fixed via a stay 270.

With such a configuration, it is possible to suppress the influence on the connection portion (block joint 250) of the outward path downstream side pipe 212 (first pipeline) and the outward path upstream side pipe 211 (second pipeline) with respect to the vibration of the vehicle body. ..

In the tractor 1,
The stay 270 is
It is formed so as to extend from a stay fixing portion 271 with the flywheel housing 4 (fixed member) toward a stay fixing portion 271 with the block joint 250,
The outgoing upstream pipe 211 (second pipeline),
The stay 270 is provided so as to extend along the extending direction.

With such a configuration, space saving can be achieved.

In the tractor 1,
The fixed member is constituted by the flywheel housing 4.

With such a configuration, the flywheel housing 4 can be used to improve the degree of freedom in design.

In the tractor 1,
The stay 270 is fixed to a mounting base 23 provided in a convex shape on the upper side of the flywheel housing 4,
The mount 23 is provided with a surface on which the upper surface of the convex shape is substantially horizontal.

With such a configuration, the stay 270 can be provided in a relatively stable and easy-to-fix location provided in the flywheel housing 4, and the vicinity of the flywheel housing 4 (a location that is relatively difficult to effectively utilize) can be effectively utilized. be able to.

In the tractor 1,
The block joint 250 is
It is provided so as to overlap with the flywheel housing 4 in a side view and to be located inside the flywheel housing 4 in the vertical and horizontal directions.

With such a configuration, the vicinity of the flywheel housing 4 (a place where it is relatively difficult to effectively utilize) can be effectively utilized. In addition, it is possible to easily prevent the block joint 250 from interfering with other members.

In the tractor 1,
The mount 23 is
The stay 270;
The bonnet support member 24 is attached.

With such a configuration, the stay 270 and the bonnet support member 24 can also serve as places to be attached (because there is no need to provide a dedicated place for attaching each), so that the vicinity of the flywheel housing 4 (relatively effective utilization) It is possible to make effective use of difficult places).

The outward downstream pipe 212 according to the present embodiment is an embodiment of the first pipeline.
Further, the outward upstream pipe 211 according to this embodiment is an embodiment of the second pipeline.
The block joint 250 according to this embodiment is an embodiment of the joint.
The flywheel housing 4 according to the present embodiment is an embodiment of the fixed member.
The mount 23 according to the present embodiment is an embodiment of the mount.

Although the embodiment of the present invention has been described above, the present invention is not limited to the above-described configuration, and various modifications can be made within the scope of the invention described in the claims.

For example, the pipes to which the block joint 250 is connected are not limited to the forward-path upstream pipe 211 (second pipe line) and the forward-path downstream pipe 212 (first pipe line) according to the present embodiment, and any pipe may be used. Can be connected. Further, in the present embodiment, the outward route upstream side pipe 211 is made of rubber and the outward route downstream side pipe 212 is made of metal, but the present invention is not limited to this. That is, the material of the pipe to which the block joint 250 is connected can be arbitrarily selected. Further, the fluid flowing through the pipe to which the block joint 250 is connected is not limited to oil and may be any fluid.

Although the block joint 250 is formed of a substantially hexahedron, it may be formed of any polyhedron such as a substantially octahedron.

Further, although the block joint 250 is fixed to the flywheel housing 4, it may be fixed to a member different from the flywheel housing 4. Further, although the block joint 250 is attached to the attachment base 23 (for attaching the bonnet support member 24), the block joint 250 can be attached to any position of the flywheel housing 4. The block joint 250 may be directly attached to the attachment base 23 without the stay 270.

1 tractor 10 bonnet 30 vent hole 31a non-overlapping part 32a non-overlapping part 40 cooling fan 50 radiator 60 oil cooler 70 fuel cooler 80 condenser 90 cooling unit 100 straightening plate 110 right side straightening plate 120 right side cutout 150 left side straightening plate 160 left side cutout

Claims (8)

A hood with a vent on the left and right side,
A fan provided inside the bonnet, which takes in air outside the bonnet into the inside through the ventilation hole,
A cooling unit provided inside the bonnet in front of the fan, for cooling the fluid to be cooled by the air taken in by the fan;
A pair of straightening vanes provided inside the bonnet between the ventilation hole and the cooling unit, and having a notched portion that is substantially rectangular in a side view and is open forward and upward,
Work vehicle equipped with. The notch is
Has a corner whose angle by two sides is approximately 90 degrees,
The work vehicle according to claim 1. In the notch of the pair of straightening vanes,
Includes a notch with a step-like step that descends forward,
The work vehicle according to claim 1. In the notch of the pair of straightening vanes,
Includes a notch formed in a notch shape at the corner of the mouth opened to the front,
The work vehicle according to any one of claims 1 to 3. The ventilation hole of the bonnet,
A first portion that overlaps the current plate in a side view, and a second portion that does not overlap,
The second part is
It is provided so as to straddle the lower end of the cutout in the vertical direction.
The work vehicle according to any one of claims 1 to 4. The cooling unit is
Having a plurality of coolers whose cooling targets are different from each other,
The plurality of coolers,
A first cooler, and a second cooler provided in front of the first cooler and having a height position of an upper end lower than that of the first cooler,
In the notch of the pair of straightening vanes,
A cutout portion provided at a position spaced apart from the first cooler in a front view is included,
The work vehicle according to any one of claims 1 to 5. In the notch of the pair of straightening vanes,
A cutout portion provided above the second cooler in a side view is included,
The work vehicle according to claim 6. The second cooler is
A third cooler, and a fourth cooler provided in front of the third cooler,
The third cooler and the fourth cooler,
It is provided so that one side on the left and right side does not overlap and the other side on the left and right sides overlap in front view
The notch of the pair of straightening vanes,
In a side view, the cutout portion on the left and right side is formed larger than the cutout portion on the left and right side,
The work vehicle according to claim 6 or 7.

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