JP2010270870A - Lubricating structure of third differential gear of in-line tandem type final reduction gear - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lubricating structure of a third differential gear of an in-line tandem type final reduction gear satisfactorily lubricating the third differential gear at any rotational condition and having no risk that the third differential gear is thermally damaged. <P>SOLUTION: An oil path (1g, 2g) for lubrication is provided on a ceiling part of a differential gear carrier (1) and a carrier cover (2), one end (1ge) of the oil path (1g) for lubrication is opened near the outer edge of a ring gear (16) and the other end of the oil path (2g) for lubrication is opened near the third differential gear (3). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a lubrication structure for a third differential gear of an inline tandem type final reduction gear in a rear front shaft of a rear biaxial vehicle in which a rear front shaft and a rear rear shaft are both drive shafts.

In a large vehicle having two rear shafts such as a large dump truck T as shown in FIG. 2 or a heavy-duty carrying vehicle or a tractor head, the rear front shaft Arf and the rear rear shaft Arr are both drive shafts. There may be.
The rear front shaft Arf is mounted with an inline tandem type final reduction gear (hereinafter referred to as “rear front shaft reduction gear” or “reduction gear”) 100D having a third differential gear.
On the other hand, a so-called “single reduction type” speed reducer 200D is mounted on the rear rear shaft Arr. Here, a single reduction type speed reducer (hereinafter referred to as “rear and rear axle speed reducer”) is also used in a vehicle driven by only the rear front axle although it is a rear biaxial vehicle.

The rotational force of the engine E is shifted by the transmission and input to the rear front shaft speed reducer 100D via the propeller shaft P.
The rotational force of the engine E input to the rear front shaft reduction gear 100D is divided into the rear front shaft Arf side and the rear rear shaft Arr side.

Hereinafter, the reduction gear 100D for the rear front shaft will be described with reference to FIG.
In FIG. 3, the speed reducer 100 </ b> D includes a differential gear carrier (hereinafter referred to as “differential carrier”) 1, a carrier cover 2, and a third differential gear (hereinafter referred to as “third differential”) 3.
Further, the speed reducer 100D includes an input shaft 4, a through shaft 5, a divider gear 6, a pinion gear 7, and a pinion 8. The through shaft 5 passes through the cylindrical shaft portion 61 of the divider gear 6.

The third differential 3 is composed of four bevel gears. That is, a front differential gear (hereinafter referred to as “front differential gear”) 31, a rear differential gear (hereinafter referred to as “rear differential gear”) 32, and a pair of differential pinions (hereinafter referred to as “diff pinion”) 33. , 34.
The input shaft 4 has a carrier portion 40, and the carrier portion 40 accommodates the gears 31 to 34 of the third differential 3 in a rotatable manner.
The front differential gear 31 always meshes with the front end portion 51 of the through shaft 5 by serration.
The rear differential gear 32 always meshes with the front end of the shaft portion 61 of the divider gear 6 by serration.

A differential lock sleeve (clutch sleeve) 9 is interposed in an intermediate portion of the through shaft 5. The differential lock sleeve 9 is configured to move along the through shaft 5 by an actuator (not shown) so that the relative rotation between the divider gear 6 and the through shaft 5 can be selected.
An output flange yoke 10 is attached to the rear end portion 52 of the through shaft 5 so that a driving force is transmitted to a rear rear shaft (not shown).

The divider gear 6 is rotatably supported by a pair of roller bearings (first bearings) 11.
The pair of roller bearings 11 are attached to the vicinity of the front end of the carrier cover 2 via the first bearing support member 12.
The pinion 8 is rotatably supported by a pair of roller bearings (second bearings) 13.
The pair of roller bearings 13 are attached to the vicinity of the front end (left end portion in FIG. 3) of the differential carrier 1 via the second bearing support member 14.

The divider gear 6 meshes with the pinion gear 7, and the pinion gear 7 is fixed integrally with the shaft portion 82 of the pinion 8.
The pinion body 81 of the pinion 8 meshes with the ring gear 16.

In the rear front shaft reduction gear 100 </ b> D as shown in FIG. 3, the lubrication to the third differential 3 is performed by scooping up lubricating oil by the pinion gear 7 and the divider gear 6.
More specifically, the oil accumulated in the bottom 1 b of the differential carrier 1 is scraped up by the pinion gear 7 and the divider gear 6 and reaches the oil passage 21 formed in the ceiling portion of the carrier cover 2.
The oil reaching the oil passage 21 is introduced into the carrier portion 40 of the input shaft 4 accommodating the third differential 3 via the oil passage 12g formed in the first bearing support member 12, and lubrication of the third differential 3 is performed. Is done.
The flow of the lubricating oil is indicated by an arrow Fo1 in FIG.

However, in the lubrication according to the related art as described above, even if the lubricating oil is scraped up by the pinion gear 7 and the divider gear 6, the lubricating oil that has been scraped up but has not entered the oil passage 21. When the oil drops, it collides with the falling lubricating oil and cannot reach the oil passage 21.
If the lubricating oil does not reach the oil passage 21, the amount of lubricating oil that reaches the third differential 3 is reduced.
Alternatively, the lubricating oil scraped up by the pinion gear 7 and the divider gear 6 bounces off the inner wall of the carrier cover 2 and collides with the lubricating oil moving upward (taken up by the pinion gear 7 and the divider gear 6). Thus, it is obstructed that the lubricating oil reaches the oil passage 21, that is, the lubricating oil is supplied to the third differential 3.

For the above reasons, in the conventional lubrication system (supplied with lubricating oil to the third differential 3) described with reference to FIG. 3, there is a possibility that the lubricating oil may not be sufficiently supplied to the third differential 3.
The phenomenon that the lubricating oil is not sufficiently supplied to the third differential 3 is particularly noticeable when the vehicle has to travel at a low speed and a high output, and in the worst case, the third differential 3 may be burned. is there.

In FIG. 3, the arrow R indicates the rotation direction of the ring gear 16, and the symbol Lo indicates the liquid level of the lubricating oil. Reference numeral Fox denotes a flow of lubricating oil that is swept up by the ring gear 16.
The ring gear 16 has a larger area immersed in the lubricating oil accumulated at the bottom of the axle housing 20 than the pinion gear 7. Accordingly, a large amount of oil is scraped up by the ring gear 16.
However, in the prior art shown in FIG. 3, the oil scooped up by the ring gear 16 does not contribute to the lubrication of the third differential 3 at all.

As another conventional technique, for example, a lubrication device for a final reduction gear that appropriately catches oil and ensures good lubrication even when the rotational speed of a ring gear is slow has been proposed (see Patent Document 1).
However, the related art (Patent Document 1) does not mention so-called “third differential” lubrication, and does not solve the above-described problem.

Japanese Utility Model Publication No. 5-22925

  The present invention has been proposed in view of the above-described problems of the prior art, and the in-line tandem type end product in which the third differential is well lubricated under any rotation conditions and the third differential is not susceptible to thermal damage. The purpose is to provide a third differential lubrication structure for the reducer.

The lubrication structure of the third differential gear of the inline tandem type final reduction gear of the present invention is the third structure of the inline tandem type final reduction gear (100) having the differential gear carrier (1), the carrier cover (2) and the third differential gear (3). In the lubricating structure of the differential gear (3), lubricating oil passages (1g, 2g) are provided in the ceiling portions of the differential gear carrier (1) and the carrier cover (2), and one end (1ge) of the lubricating oil passage (1g) is provided. ) Is opened near the outer edge of the ring gear (16), and the other end of the lubricating oil passage (2g) is opened near the third differential gear (3).
The lubricating oil passages (1g, 2g) are preferably configured to extend in the direction parallel to the tangent to the ring gear (16) at the outer edge of the ring gear (16).

  In the present invention, the lubricating oil passage (1g, 2g) is preferably formed in a straight line over the entire length.

  Further, in the present invention, it is preferable that one end (1ge) of the lubricating oil passage (1g) is formed in a tapered shape so that the flow passage area increases as the end portion is approached.

  In the present invention, it is preferable that the lubricating oil passage (1g) is provided with a branch hole (1b) in the middle of the oil passage.

According to the present invention having the above-described configuration, the lubricating oil passages (1g, 2g) are provided in the ceiling portions of the differential gear carrier (1) and the carrier cover (2), and one end of the lubricating oil passage (1g) is provided. (1ge) opens near the outer edge of the ring gear (16), and the other end of the lubricating oil passage (2g) opens near the third differential (3). Therefore, the ring gear (16) scrapes a large amount. The raised lubricating oil is introduced directly from one end (1ge) of the lubricating oil passage (1g) into the lubricating oil passage (1g) and supplied to the third differential gear (3: third differential).
Here, since the ring gear (16) has a large surface area immersed in the lubricating oil, the amount of oil scraped up by the ring gear (16) is extremely large. Therefore, a sufficient amount of lubricating oil is supplied to the third differential (3).

The lubricating oil that is scraped up by the ring gear (16) and flows through the lubricating oil passage (1g) has an effect even if, for example, the oil scooped up by the divider gear (6) and the pinion gear (7) falls. Without being received, it is reliably supplied to the third differential (3) via the lubricating oil passage (1 g).
Therefore, a sufficient amount of lubricating oil is always supplied to the third differential (3), and it is ensured that the supply of the lubricating oil is delayed and the third differential (3) is exposed to high temperature and seizure occurs. Is prevented.

  Here, if the lubricating oil passage (1g, 2g) is configured to face in a direction parallel to the tangent to the ring gear (16), the rotational force of the ring gear (16) conveys the oil to the third differential (3) side. Since it acts as a force, it is not necessary to provide a dedicated pump for circulating the oil pump.

Furthermore, in the present invention, if the lubricating oil passage (1g, 2g) is formed in a straight line over the entire length, the resistance in the oil passage (1g, 2g) is small and the lubrication is performed well.
Then, if one end (1ge) of the lubricating oil passage (1g) is tapered so that the flow passage area increases as it approaches the end portion, the lubricating oil introduced into the oil passage (1g, 2g) The amount is increased, and the lubricating performance for lubricating the third differential (3) is further enhanced.

  In addition to this, a branch hole (1b) is provided in the middle of the oil passage of the lubricating oil passage (1g), and lubricating oil is supplied to the places where lubrication is required in the differential gear carrier (1) and / or the carrier cover (2). If it is configured to dripping, sufficient lubrication oil is supplied to the places that require lubrication in the differential gear carrier (1) and / or the carrier cover (2), resulting in insufficient lubrication and associated problems. Can be wiped out.

In this way, according to the present invention, the amount of lubricating oil supplied to the third differential (3) can be greatly increased, so that the amount of lubricating oil supplied to the third differential (3) is less than the required amount in the third differential (3). A lot can be done.
And if the amount of lubricating oil supplied to the third differential (3) exceeds the required amount in the third differential (3), the amount of lubricating oil that fills the rear front shaft can be reduced, reducing initial costs and running costs. It becomes possible to do.

It is sectional drawing of the in-line tandem type final reduction gear which concerns on embodiment of this invention. It is a side view of a 3 axis vehicle which has an in-line tandem type final reduction gear. It is sectional drawing of the inline tandem type final reduction gear of a prior art.

Hereinafter, a third differential lubrication structure of an inline tandem type final reduction gear according to an embodiment of the present invention will be described with reference to FIG.
Note that the third differential lubrication structure of the inline tandem final reduction gear according to the embodiment shown in FIG. 1 differs from the lubrication structure shown in FIG. In other words, the other configuration is the same in FIG. 1 and FIG.
Therefore, in the following description given with reference to FIG. 1, a configuration different from the prior art shown in FIG. 3 will be mainly described. The configuration not specifically described below is the same as that of the conventional technology described with reference to FIG.
In FIG. 1, members similar to those in FIG. 3 are given the same reference numerals as in FIG. 3.

In FIG. 1, the ceiling portion of the differential gear carrier (hereinafter referred to as “diff carrier”) 1 (upper portion in FIG. 1: the same applies hereinafter) and the ceiling portion of the carrier cover 2 are not clear in the drawing. However, a tunnel-like oil passage 1g (differential carrier 1 side) and 2g (carrier cover 2 side) are formed.
The oil passages 1g and 2g constitute a common cross-sectional flow path in the differential carrier 1 and the carrier cover 2. In FIG. 1, the oil passages 1g and 2g are linearly formed over the entire area.
In FIG. 1, reference numeral 15 denotes a differential assembly, and the differential assembly 15 includes a ring gear 16, a third differential 3, a through shaft 5, a divider gear 6, a pinion gear 7, and a pinion 8.

One end 1ge of the oil passage 1g on the differential carrier 1 side is open near the outer edge of the ring gear 16 (the outer edge of the ring gear 16 in the radial direction).
Here, since the lubricating oil passages 1g and 2g are configured to extend in a direction parallel to the tangent line of the ring gear 16, when the ring gear 16 rotates, the ring gear 16 is scraped up by the rotational force. Lubricating oil is conveyed to the third differential 3 side (left side in FIG. 1). That is, the rotational force of the ring gear 16 acts as a force for conveying the lubricating oil to the third differential 3 side in the lubricating oil passages 1g and 2g.
Therefore, in the embodiment shown in FIG. 1, there is no need to separately provide a pump for circulating the oil pump.

Although not shown in FIG. 1, the dimension of the opening 1 ge in the width direction (direction perpendicular to the paper surface) is set so as to cover the range in which the oil scooped up by the ring gear 16 scatters.
In FIG. 1, an arrow Fo <b> 2 indicates a trajectory (or flow) of the lubricating oil moved up by the ring gear 16. An arrow Fo3 indicates the locus (or flow) of the lubricating oil that moves in the oil passages 1g and 2g.

The lubricating oil passage 1g is formed in a tapered shape so that the cross-sectional area of the passage increases as it approaches the end 1ge on the ring gear 16 side.
Therefore, the end portion 1ge of the lubricating oil passage 1g on the ring gear 16 side has a large cross-sectional area, and the lubricating oil scraped up by the ring gear 16 is easily introduced into the lubricating oil passage 1g. Yes. As a result, the amount of lubricating oil introduced into the lubricating oil passage 1g is increased, the amount of lubricating oil supplied to the third differential 3 is increased, and the lubricating performance is improved.

In FIG. 1, an oil passage 12 g is formed in the first bearing support portion seat 12. Here, the first bearing support portion seat 12 supports a bearing (a pair of roller bearings: a first bearing) 11 of the divider gear 6.
In FIG. 1, the oil passage 12 g is formed so as to be inclined downward from the right side to the left side, that is, from the carrier cover 2 toward the carrier portion 40 that houses the third differential 3.

In FIG. 1, an oil passage 40 g is formed near the upper end portion of a rear differential gear (hereinafter referred to as “rear differential gear”) 32 above the carrier portion 40, and the oil passage 40 g is formed in the carrier portion 40. Communicate.
One end of the oil passage 12g communicates with the oil passage 2g formed in the carrier cover 2, and the other end of the oil passage 12g is provided at a position facing the oil passage 40g formed in the carrier portion 40. .
That is, the oil passages 1g and 2g communicate with the inside of the carrier portion 40 via the oil passage 12g and the oil passage 40g, and the lubricating oil scraped up by the ring gear 16 is the oil passages 1g, 2g, 12g and 40g. It is supplied to the third differential 3 via the.

A branch hole 1 b is formed in the oil passage 1 g formed in the differential carrier 1.
In FIG. 1, the branch hole 1 b is formed in the vicinity of the roller bearing on the vehicle rear side (right side in FIG. 1) of the first bearing 11.
By forming the branch hole 1b, a part of the lubricating oil flowing through the oil passage 1g is dripped onto the roller bearing 11, and the roller bearing 11 is reliably lubricated.

According to the embodiment having the above-described configuration, the oil passage 1 g is provided in the ceiling portion of the differential carrier 1, and the oil passage 2 g is provided in the ceiling portion of the carrier cover 2, and one end 1 ge of the oil passage 1 g is opened near the outer edge portion of the ring gear 16. is doing.
Further, the end of the oil passage 2 g on the third differential 3 side reaches the vicinity of the third differential 3 via the oil passage 12 g formed in the support member 12.

Here, the amount of oil scooped up by the ring gear 16 (the flow of the arrow Fo2) is extremely large. A large amount of lubricating oil scraped up by the ring gear 16 is introduced into the lubricating oil passages 1 g and 2 g from the end 1 ge of the oil passage 1 g and reaches the third differential 3.
Even if the lubricating oil scraped up by the divider gear 6 and the pinion gear 7 falls inside the carrier cover 2, the lubricating oil flowing through the oil passages 1 g and 2 g reaches the third differential 3 without any influence.

  According to the illustrated embodiment, since a sufficient amount of lubricating oil is supplied to the third differential 3, the lubricating oil is stagnated, the third differential 3 is not exposed to high temperatures, and seizure of the gear occurs. Is prevented.

In the illustrated embodiment, the oil passages 1g and 2g are linearly formed over the entire length, and therefore, there is little pipe resistance when the lubricating oil moves through the oil passages 1g and 2g, and the lubricating oil is smooth. To the third differential 3.
Further, the oil passage 1g is formed in a tapered shape so that the cross-sectional area of the flow passage increases as the end portion 1ge on the ring gear 16 side is approached, and the opening area of the end portion 1ge is increased. The lubricating oil scraped up in step 1 is easily introduced into the oil passage 1g, the amount of lubricating oil supplied to the third differential 3 is increased, and the lubricating performance is further improved.

  In addition, in the illustrated embodiment, the branch hole 1b is provided in the middle of the oil passage 1g, and the lubricating oil is dropped on the first bearing 11, so that the first bearing 11 is also sufficient. Thus, it is possible to supply a sufficient amount of lubricating oil and to eliminate the lack of lubrication of the first bearing 11 and troubles associated therewith.

  In the illustrated embodiment, if the amount of lubricating oil supplied to the third differential 3 exceeds the required amount of lubricating oil in the third differential 3, the amount of lubricating oil to be filled in the rear front shaft in advance. (Filling oil amount) can be reduced. If the amount of lubricating oil filled in the rear front shaft can be reduced, the initial cost and running cost can be reduced.

The illustrated embodiment is merely an example, and is not intended to limit the technical scope of the present invention.
In the example of FIG. 1, the oil passages 1g and 2g are inclined, but the oil passages 1g and 2g may be formed horizontally. Alternatively, the horizontal portion and the inclined portion can be mixed in the oil passages 1g and 2g.
However, in order to effectively lubricate, it is preferable to avoid a change in the cross-sectional area of the flow path as much as possible and not to provide a portion where the cross-sectional area changes extremely.

DESCRIPTION OF SYMBOLS 1 ... Differential gear carrier / Differential carrier 2 ... Carrier cover 3 ... Third differential gear / Third differential 4 ... Input shaft 5 ... Through shaft 6 ... Divider gear 7 ... Pinion gear 8 ... -Pinion 10 ... flange yoke 11 ... a pair of roller bearings / first bearing 11
12... First bearing support member 13... Pair of roller bearings / second bearing 11
14 ... second bearing support member 15 ... differential assembly 16 ... ring gear 20 ... axle housing 31 ... front differential gear / front differential gear 32 ... rear differential gear / rear differential gear 33, 34 ..Differential pinion / Differential pinion 40 ... carrier portion 51 ... front end portion 52 ... rear end portion 61 ... shaft portion 81 ... pinion body 82 ... shaft portion 1g, 2g ... oil Road 100 ... Final reduction gear

Claims (4)

  In a lubrication structure of a third differential gear of an inline tandem type final reduction gear having a differential gear carrier, a carrier cover, and a third differential gear, a lubricating oil passage is provided in a ceiling portion of the differential gear carrier and the carrier cover. A lubrication structure for a third differential gear of an inline tandem type final reduction gear, characterized in that one end opens in the vicinity of the outer edge of the ring gear and the other end of the lubricating oil passage opens in the vicinity of the third differential gear.   The lubricating structure for a third differential gear of an inline tandem type final reduction gear according to claim 1, wherein the lubricating oil passage is formed linearly over the entire length.   The third end of the inline tandem type final reduction gear according to any one of claims 1 and 2, wherein one end of the lubricating oil passage is formed in a tapered shape so that the flow passage area increases as it approaches the end portion. Differential gear lubrication structure.   2. The lubricating oil passage according to claim 1, wherein a branch hole is provided in the middle of the oil passage so that the lubricating oil is dropped in a differential gear carrier and / or in a carrier cover where lubrication is required. The lubrication structure of the third differential gear of the inline tandem type final reduction gear of any one of.

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