JPH06128847A - Oil feeder for rotating shaft in loom - Google Patents

Abstract

PURPOSE:To supply oil to a site requiring the lubrication of a rotating shaft in a loom without using a lubricating pump. CONSTITUTION:An idle shaft 15 and a main shaft 21 enter the interior of an oil storage tank 14 and a driven bevel gear 20 and a driving bevel gear 22 are secured to the entering ends so as to mesh therewith. A guide passage (L) is formed in the oil storage tank 14 and an oil storage pond (P) is formed at the terminal end thereof. An oil guide passage (16a) in a tappet shaft 16 is connected to the oil storage pond (P) with a feed pipe 29 and an oil in the oil storage pond (P) is fed into the interior of the oil guide passage (16a). An oil guide plate 25 is interposed between the starting end of the guide passage (L) and the driven bevel gear 20. The oil splashed with the driven bevel gear 20 is passed along the oil guide plate 25 and drawn into the guide passage (L).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is provided with a lubricating oil storage tank on a drive transmission path for obtaining a driving force from a loom drive source, and a connecting portion of a rotary drive transmission member constituting the drive transmission path is stored with a lubricating oil. The present invention relates to an oil supply device for a rotating shaft of a loom that is immersed in oil stored in a tank.

[0002]

2. Description of the Related Art A structure for supplying lubricating oil to a lubrication necessary portion of a loom is disclosed, for example, in Japanese Utility Model Laid-Open No. 51-30261, Japanese Patent Laid-Open No. 58-126348 or Japanese Utility Model Laid-Open No. 63-1.
It is disclosed in Japanese Patent No. 40080.

In the oil supply apparatus of Japanese Utility Model Laid-Open No. 51-30261, an oil-containing pad that meshes with a gear is fitted on a hollow shaft, and the hollow shaft is connected to an oil storage tank. Oil in the oil storage tank penetrates into the pad through a large number of small holes on the hollow shaft to lubricate a gear meshing with the pad.

In the oil supply apparatus disclosed in Japanese Patent Laid-Open No. 58-126348, the oil is supplied to the lubrication necessary portion of the rotary shaft by the increase of the oil pressure accompanying the operation of the loom. In the oil supply apparatus disclosed in Japanese Utility Model Laid-Open No. 63-140080, an oil supply nozzle faces a connecting shaft portion of a jack lever for vertically moving a heald frame and a mounting arm for attaching a spring, and the oil supply nozzle in an oil storage tank is used to supply the oil supply nozzle. It is designed to supply oil to.

[0005]

[Problems to be Solved by the Invention]
In the oil supply device disclosed in Japanese Patent No. 30261, an oil storage tank dedicated to gear lubrication is installed above the pad.
Such a configuration in which a dedicated oil storage tank is prepared for each area requiring lubrication is very troublesome for maintenance management.

Japanese Utility Model Laid-Open No. 63-1400 using an oil pump
The refueling device disclosed in Japanese Patent No. 80 has a drawback that the cost is increased due to the use of the refueling pump, and the maintenance of the refueling pump is complicated. Moreover, the oil storage tank is exclusively used for lubrication of the connecting shaft portion between the jack lever and the mounting arm, and this dedicated structure causes the same problem as the oil supply device of Japanese Utility Model Laid-Open No. 51-30261.

In the oil supply apparatus disclosed in Japanese Patent Laid-Open No. 58-126348, it is premised that the hydraulic pressure increases with the operation of the loom.
Therefore, a booster mechanism is required. This is the actual exploitation 63-
It brings about the same problem as the oil supply device disclosed in Japanese Patent No. 140080.

An object of the present invention is to provide an oil supply device for a rotating shaft of a loom that can use oil in an existing oil storage tank for lubrication without using an oil supply pump.

[0009]

Therefore, according to the present invention,
The loom is provided with an oil storage tank on the drive transmission path for obtaining the driving force from the loom drive source, and the rotation of the loom in which the connecting portion of the rotary drive transmission member forming the drive transmission path is immersed in the stored oil in the oil storage tank. The oil storage part is provided with an oil pumping part provided in the connection part so as to pump up the stored oil in the oil storage tank by the rotation of the drive transmission member, and an oil storage part for storing the oil pumped by the oil pumping part. Is connected to the lubrication necessary portion of the rotary shaft that constitutes the drive transmission path to configure an oil supply device.

[0010]

With the operation of the loom, the oil pumping section rotates, and the stored oil in the oil storage tank is pumped up and sent to the oil storage section for storage. The oil stored in the oil storage portion is supplied to the lubrication necessary portion of the rotary shaft through the oil supply passage. The oil pumping unit is, for example, a bevel gear fixed to a rotary shaft for transmitting the rotational drive, and the stored oil in the oil storage tank for lubricating the gear mechanism is pumped up to the guide passage by the rotation of the bevel gear.

By allowing the oil pumped up by the oil pumping section to pass through the guide passage above the oil storage surface in the storage tank, the degree of freedom in setting the arrangement position of the oil storage section is increased. This high degree of freedom facilitates connection between the lubrication-required portion of the rotating shaft and the oil storage portion, that is, it is easy to supply oil from the oil storage tank to the lubrication-required portion of the rotating shaft.

If an inclined oil guide having an inclined surface is interposed between the inlet of the guide passage and the oil pumping section, the oil can be easily pumped up to the guide path. If the guide passage is a pipe, the degree of freedom of bending the pipe increases the degree of freedom in setting the route of the guide passage, and it becomes easy to supply oil from the oil storage tank to a portion of the rotating shaft that needs lubrication.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT An embodiment embodying the present invention will now be described with reference to FIGS.
It will be described with reference to FIG. FIG. 2 shows an opening device. A plurality of jack levers 2 are rotatably supported side by side via a support shaft 3 on opening brackets 1 (only one is shown) on both side frames of the loom. A heddle frame 4 is suspended and supported by a suspension rope 5 at one end of the jack lever 2. A spring hanger 6 is attached to the other end of the jack lever 2.
Are suspended and supported via a connecting rope 5A. A hanger bracket 7 is attached below the spring hanger 6, and an opening spring 8 is stretched between the hanger bracket 7 and the spring hanger 6.

The hanging rope 5 is connected to a cam lever 10 via a guide roller 9. The cam lever 10 swings around the support shaft 12 as the tappet cam 11 rotates. The jack lever 2 swings by the cooperation of the spring action of the opening spring 8 and the swinging of the cam lever 10, and the heddle frame 4 moves upward and downward.

A contact portion between the cam follower 10a of the cam lever 10 and the tappet cam 11 is immersed in the stored oil U ₁ in the oil storage tank 13. FIG. 1 shows an oil storage tank 13. A second oil storage tank 14 is arranged in parallel with the oil storage tank 13. An idle shaft 15 is rotatably supported in the oil storage tank 13 and one end of the idle shaft 15 is rotatably supported.
4 is protruding into. A tappet shaft 16 is erected and supported in the oil storage tank 13 in parallel with and fixed to the idle shaft 15. A tappet bush 17 is rotatably fitted to the tappet shaft 16, and the tappet bush 1
A tappet cam 11 is fixedly attached to 7.

An idle gear 18 is fixed to the idle shaft 15, and a tappet gear 19 is fixed to the tappet bush 17 so as to mesh with the idle gear 18. As shown in FIG. 1 and FIG. 3, the driven bevel gear 2 is attached to the protruding end of the idle gear 18 protruding into the oil storage tank 14.
0 is fixed. A main shaft 21 projects into the oil storage tank 14. The main shaft 21 forms a right angle with the idle shaft 15, and a drive bevel gear 22 is fixed to the protruding end of the main shaft 21 so as to mesh with the driven bevel gear 20.
The main shaft 21 is rotationally driven by a loom drive motor (not shown). The rotation driving force of the main shaft 21 is the bevel gears 22, 2
0, the idle shaft 15, the idle gear 18, the tappet gear 19 and the tappet bush 17 through the tappet cam 1
1 is transmitted. By this rotation drive transmission, the tappet bush 17 and the tappet cam 11 rotate about the tappet shaft 16.

A guide bottom 23 is horizontally mounted on the three inner wall surfaces of the oil storage tank 14, and a guide wall 24 is provided upright on the inner edge of the guide bottom 23. The guide bottom 23 and the guide wall 24 are the drive bevel gear 22 and the driven bevel gear 2.
A guide passage L surrounding 0 is formed. As shown in FIG. 4, the guide bottom 23 is above the main shaft 21, the upper edge of the guide wall 24 is above the drive bevel gear 22, and the oil storage tank 14 is
Is below the lid 14a.

The starting end of the guide passage L is driven by the driven bevel gear 2.
It is located to the side of 0 and the side opposite to the drive bevel gear 22. An oil guide plate 25 is interposed between the starting end of the guide wall 24 and the upper portion of the drive bevel gear 22. The oil guide plate 25 is inclined upward from the drive bevel gear 22 side to the upper edge of the guide wall 24.

The terminal end of the guide passage L is located directly above the main shaft 21. The storage step wall 26 is connected to the terminal end of the guide bottom 23, and the storage bottom 27 is connected to the lower edge of the storage step wall 26. A storage wall 28 is connected to the guide wall 24, the storage step wall 26, and the storage bottom 27.
6, the storage bottom 27 and the storage wall 28 form a storage pond P. Figure 4
As shown in, the storage bottom 27 is located above the central axis of the tappet shaft 16.

As shown in FIG. 1, an oil guide passage 16a is formed through the central axis of the tappet shaft 16. Oil guide passage 1
A plurality of small oil supply holes 16b are connected to 6a from the peripheral surface of the tappet shaft 16. A supply pipe 29 is interposed between the bottom of the reservoir P and the end of the tappet shaft 16 with a slight inclination, and the reservoir P and the oil guide passage 16a are connected to each other.
Are in communication with each other.

When the operation of the loom is started, the main shaft 21 rotates in the direction indicated by the arrow Q in FIGS. 1 and 4, and the driven bevel gear 20 rotates in the direction indicated by the arrow R. Storage tank 14
The stored oil U ₂ therein is repelled by the rotation of the driven bevel gear 20, and a part of this repelled oil is guided to the guide passage L along the oil guide plate 25. The oil guided to the guide passage L flows into the reservoir P and accumulates therein. The oil stored in the reservoir P is guided from the supply pipe 29 to the oil guide passage 16a in the tappet shaft 16 and supplied from the small oil supply hole 16b to the sliding contact portion between the tappet shaft 16 and the tappet bush 17.

The configuration in which the oil pumped up by the driven bevel gear 20 is passed through the guide passage L above the oil storage surface in the storage tank 14 increases the degree of freedom in setting the position of the reservoir P. Due to this high degree of freedom, tappet shaft 1
It becomes easy to connect the lubrication-required portion between the reservoir 6 and the tappet bush 17 to the reservoir P. Therefore, it becomes easy to supply oil from the oil storage tank 14 to the lubrication necessary portion between the tappet shaft 16 and the tappet bush 17.

In the oil supply device using the oil supply pump, the adoption of the oil supply pump itself causes a cost increase. In this embodiment, the rotary drive force of the loom drive motor is applied to the tappet cam 1.
The driven bevel gear 20 serving as a connecting portion between the main shaft 21 and the idle shaft 15, which constitutes a part of the drive transmission path transmitted to the motor 1, plays the role of an oil supply pump. That is, the rotating action of the driven bevel gear 20 draws up the stored oil U ₂ in the storage tank 14 to the guide passage L at a position higher than the oil guide passage 16a in the tappet shaft 16. In the illustrated example of FIG. 4, the central axis of the tappet shaft 16 is above the oil level of the stored oil U ₂ , but the stored oil U
_The oil guide passage 1 by pumping ₂ onto the guide passage L
6a can be refueled. Such a driven bevel gear 20
By using the existing member, it is possible to suppress the cost increase of the oil supply device.

Further, the gear pump type oil supply pump not only accelerates the deterioration of oil but also causes foaming. Bubbling is the oil guide passage 16
Clogged in a or the small oil supply hole 16b to cause poor oil supply. In this embodiment, which does not use an oil supply pump, the life of oil is extended. Further, even if the oil pumped up on the guide passage L by the driven bevel gear 20 foams, the foaming disappears on the guide passage L or the reservoir P. Lid 1
A gap between 4a and the upper edge of the guide wall 24 is provided to remove air from the disappeared bubbles. Induction passage L
This is because the oil above may fill up.

The gear pump type oil pump raises the temperature of the oil. When the oil temperature rises, the lubricating performance of oil decreases.
In this embodiment that does not use an oil supply pump, the temperature of the oil does not rise so much and the oil that remains on the guide passage L and the reservoir P cools. Therefore, deterioration of lubrication performance of oil is prevented.

When the rotational speed of the driven bevel gear 20 is high, the splashed oil rises up onto the guide passage L without the oil guide plate 24. However, when the rotational speed of the driven bevel gear 20 is low, the guiding action of the oil guide plate 24 plays a large role in pumping the oil onto the guide passage L. Therefore, the adoption of the oil guide plate 24 is a constituent requirement of the oil supply device capable of coping with the change of the rotation speed of the loom.

The oil guide passage 16a is located below the bottom of the reservoir P. Therefore, the own weight pressure of the oil in the reservoir P is directly applied to the small oil supply hole 16b. This pressure boosting structure is the tappet shaft 1
The small clearance between 6 and the tappet bush 17 contributes to reliable oil supply to the lubrication-needed portion.

Of course, the present invention is not limited to the above-mentioned embodiment, and the guide passage L and the reservoir P may be formed by bending the pipe 30 as shown in FIG. 5, for example. It is desirable to provide an air vent hole 30a on the upper surface of the pipe 30. Due to the high degree of freedom of bending the pipe 30, the degree of freedom in setting the route of the guide passage L is higher than that in the above-described embodiment.

In each of the above-mentioned embodiments, the case where the main shaft 21 rotates in the direction of the arrow Q is premised, but when the main shaft 21 rotates in the opposite direction, the guide passage L becomes unnecessary and the oil be splashed up by the driven bevel gear 20. Is pumped directly to reservoir P.

Further, according to the present invention, a pumping impeller may be attached to the idle shaft 15 in each of the above-described embodiments in the oil storage tank 14, and oil may be pumped up by the impeller. Further, according to the present invention, oil may be supplied from the oil supply tank 14 to a lubrication necessary portion of a rotary shaft other than the tappet shaft.

[0031]

As described above in detail, according to the present invention, the oil in the oil storage tank is pumped up by utilizing the rotating action of the rotary drive transmission member which constitutes the drive transmission path for obtaining the driving force from the loom drive source. Since the pumping oil is supplied to the lubrication necessary portion of the rotary shaft that constitutes the drive transmission path, the oil in the existing oil storage tank can be used for lubrication without using an oil supply pump to achieve good lubrication. It has an excellent effect.

[Brief description of drawings]

FIG. 1 is a plan view of an oil storage tank.

FIG. 2 is a front sectional view of an opening device.

FIG. 3 is an enlarged perspective view of a main part of an oil storage tank.

4 is a cross-sectional view taken along the line AA of FIG.

FIG. 5 is an enlarged front sectional view of an essential part showing another example.

[Explanation of symbols]

14 ... Oil storage tank, 15 ... Idle shaft, 16 ... Tappet shaft, 17 ... Tappet bush, 20 ... Driven bevel gear serving as oil pumping section, 23 ... Induction bottom forming an induction passage,
24 ... Guide wall forming guide passage, 25 ... Oil guide plate serving as oil guide part, 26 ... Storage step wall forming reservoir, 27 ... Storage bottom forming reservoir, 28 ... Storage forming reservoir Walls, 29 ... Supply pipes, 30 ... Pipes, P ... Reservoir serving as an oil reservoir, L ... Induction passages, U ₂ ... Stored oil.

Claims (5)

[Claims] 1. A loom in which an oil storage tank is provided on a drive transmission path for obtaining a driving force from a loom drive source, and a connection portion of a rotary drive transmission member constituting the drive transmission path is immersed in the stored oil in the oil storage tank. An oil pumping unit provided in the connection unit so as to pump up the stored oil in the oil storage tank by the rotation of the rotary drive transmission member; and an oil storage unit that stores the oil pumped by the oil pumping unit, An oil supply device for a rotary shaft of a loom, wherein an oil storage part is connected to a lubrication necessary portion of the rotary shaft that constitutes the drive transmission path. 2. A guide passage for guiding the oil pumped up by the oil pumping portion to the oil storage portion is provided in the oil storage tank, and the guide passage is above the storage oil surface in the oil storage tank. An oil supply device for a rotating shaft in the loom according to claim 1. 3. The oil supply device for a rotating shaft of a loom according to claim 1, wherein an inclined oil guide portion having an inclined surface is provided on the rotation direction side of the oil pumping portion. 4. The oil pumping section is a bevel gear.
A lubrication device for a rotating shaft of the loom according to item 1. 5. An oil supply device for a rotating shaft in a loom according to claim 1, wherein a pipe is connected between the oil pumping portion and the lubrication necessary portion.