JP2562418B2 - Power transmission starter - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a starting device for a power transmission device, and more specifically, it is possible to prevent a rush current to a prime mover (main motor) by a simple mechanical mechanism and also to enable continuously variable transmission. Starter.

[0002]

2. Description of the Related Art In a power transmission device having a very large load such as a tunnel excavator, its prime mover (motor)
When starting up, a large current flows up to about 6 times that during steady operation. In order to receive such a large current (rush current) at the time of startup, a large capacity cable must be connected to the input part of the prime mover only for the rush current. In addition, in the case of a device such as a tunnel excavator that moves deeper in response to excavation of a tunnel, the length from the power source of this large-capacity cable must be extended as the excavation progresses. In this type of power transmission device, it is inevitable that the cost will be extremely high unless the above measures for preventing the rush current are taken.

Conventionally, various measures have been studied mainly in terms of electrical mechanism as a rush current preventing measure in this type of power transmission device, but all of them have a problem that the mechanism is complicated and expensive. there were.

[0004]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a starting device capable of preventing a rush current to a prime mover (main motor) by arbitrarily adjusting a starting time by a relatively simple mechanical mechanism. Especially. Another object of the present invention is to provide a starting device that not only prevents rush current but also functions as a continuously variable transmission.

[0005]

The starting device of the present invention which achieves the above object is a power transmission device in which an output shaft of a prime mover is connected to a driven part through a speed change part composed of a planetary gear mechanism. The internal gear of the mechanism is made rotatable, the worm wheel side of the worm gear mechanism having a self-locking function is connected to the internal gear, and the worm side is further connected to a small motor that rotates in a direction to release the self-locking function. It is characterized by having done.

In this way, the internal gear of the planetary gear mechanism is made rotatable, the worm gear mechanism having a self-locking function is connected to the internal gear, and the worm gear mechanism is rotated in the direction for releasing the self-locking function. Since a small motor is connected, when the small motor is turned on by turning it on at the time of startup, the rotation of the small motor causes the prime mover (main motor) to idle, and prevents the output shaft of the planetary gear mechanism from rotating. .

Therefore, when the prime mover (main motor) is switched on and started in this state, the prime mover can be gradually shifted from 0 revolutions to the rated revolution under a heavy load on the driven part side. That is, it is characterized in that the prime mover (main motor) is idly rotated to the rated rotation under a load, and then the prime mover is turned on, whereby rush current to the prime mover can be prevented. Further, when the rotational speed of the small motor is gradually reduced, the rotational speed of the output shaft of the planetary gear mechanism (transmission unit) to which the driven portion is connected is gradually changed from 0 to the rated rotation smoothly. You can

Further, since the reaction force of the internal gear of the planetary gear mechanism is balanced with the worm gear mechanism having the self-locking function, it can be used as a small motor for rotating the worm gear mechanism in the direction to unlock the self-locking. Would be of very small capacity. Further, when the small motor is a variable speed motor, the planetary gear mechanism can be made to function as a continuously variable transmission by arbitrarily changing the rotation speed.

[0009]

The present invention will be described in detail below with reference to the embodiments shown in the drawings. FIG. 1 is a schematic view showing an example of a power transmission device provided with a starting device of the present invention. Reference numeral 1 is a prime mover of a main motor, 20 is a planetary gear mechanism that constitutes a transmission unit (reduction unit), and 30 is a driven unit such as a tunnel excavator. The output shaft 2 of the prime mover 1 is connected to the input shaft 3 of the planetary gear mechanism 20, and the output shaft 4 of the planetary gear mechanism 20 is connected.
Is connected to the driven part 30.

The planetary gear mechanism 20 meshes a plurality of (usually three) planetary gears 7 in a circumferential direction between a sun gear 5 and an internal gear 6 which are concentrically arranged. The internal gear 6 is configured to be rotatable. The planetary gear mechanism 20 having such a structure connects the input shaft 3 to the sun gear 5, and the plurality of planetary gears 7 are supported by the carrier 8.
The output shaft 4 is connected to the rotation center of the carrier 8.

A gear 10 having a diameter smaller than that of the internal gear 6 is coaxially connected to the rotatable internal gear 6. A gear 11 having a larger number of teeth is meshed with the gear 10 to form a speed increasing device 12, a worm gear mechanism 13 is connected to the speed increasing device 12, and a small motor 16 is connected to the worm gear mechanism 13. It is connected. The worm gear mechanism 13
The worm wheel 14 and the worm 15 are meshed with each other, and the speed increasing device 12 is provided on the worm wheel 14 side.
And the output shaft 17 of the small motor 16 is connected to the worm 15 side. Although the relationship between the worm 15 and the small motor 16 is shown as a conceptual diagram in FIG. 1, more precisely, when viewed from the axial direction of the worm wheel 14, FIG.
It looks like.

Due to its function, the worm gear mechanism 13 does not transmit power from the worm wheel 14 to the worm 15 side and self-locks. In other words, the worm gear mechanism 13 is connected to the speed increasing device 12 and the small motor 16 as described above, so that the speed increasing device 12
The power transmission from the motor to the small motor 16 is self-locked.

On the other hand, the small motor 16 connected to the worm 15 is set so that its rotation direction rotates in a direction in which the self-locking function of the worm gear mechanism 13 is released. Due to such a connection, the capacity of the small motor 16 may be such that the rotational force is substantially equal to 0 for rotating the worm 15, which is extremely smaller than that of the prime mover 1. It may be one. This small motor 16 has a flywheel 18 on its output shaft 17.
A brake 19 is also attached.

In the power transmission device having the above structure,
The speed reduction ratio 1 / m of the planetary gear mechanism 20, the speed increase ratio m _{1 of} the speed increasing device 12, and the speed reduction ratio 1 / m ₀ of the worm gear mechanism 13 respectively set the rotational speed x of the output shaft 4 of the planetary gear mechanism 20 to 0. When the speed is set to 1, the rotational speed N of the prime mover 1 is equal to the rated rotational speed N _f.
In addition, the rotation speed n of the small motor 16 is set to rotate at the rated rotation speed n _f .

[0015] For example, the rated rotational speed n _f of the rated speed N _f, and a small motor 16 of the engine 1, respectively 1500rp
m, the reduction ratio 1 / m of the planetary gear mechanism 20 is 1/10,
When the speed reduction ratio 1 / m ₀ of the worm gear mechanism 13 is 1/50, and the speed increase ratio m ₁ of the speed increasing device 12 is set to m ₁ = 5.53, the rotation speed p of the internal gear 6 is 166. It may be 6 rpm.

That is, the rotational speed x of the output shaft 4 of the planetary gear mechanism 20 is x = (N + p) (1 / m) -p, where p is the rotational speed of the internal gear 6, and therefore the above-mentioned setting is made. X = 0, N = 1500
In the following case, 0 = (1500 + p) (1 / m) −p ∴p [1- (1 / m)] = (1 / m) · 1500 The reduction ratio 1 / m of the planetary gear mechanism 20 is 1 / m by the above setting.
Since it is set to 10, p [1− (1/10)] = (1/10) × 1500 ∴p = 166.6 On the other hand, the rated rotation speed n _f of the small motor 16 is 1500 rp
m, reduction ratio of worm gear mechanism 13 1 / m ₀ = 1/5
0 and the speed increasing ratio of the speed increasing device 12 is m ₁ = 5.53, then n _f (1 // m ₀ ) m ₁ = 166.6 and p = 166.6.

When activating the above-mentioned power transmission device,
First, the small motor 16 is started, and then the prime mover (main motor) 1 is started. Next, small motor 1
The rotation speed of 6 is controlled to be gradually reduced to 0 within an arbitrary time. The deceleration of the small motor 16 can be performed by controlling the brake 19, and the time until the rotational speed of the small motor 16 is set to 0 can be adjusted by the flywheel 18.

In the above starting operation, since the output shaft 4 of the planetary gear mechanism 20 is heavily loaded on the driven part 30 at the beginning of the starting operation, the small motor 16 is started to activate the internal gear 6 of the planetary gear mechanism 20. While the engine is rotating at 166.6 rpm described above, even if the prime mover 1 is started, its rotational force is not transmitted from the planetary gear mechanism 20 to the output shaft 4 (rotation speed x = 0).

When the small motor 16 is switched off, the power of the prime mover (main motor) 1 is gradually transmitted from the planetary gear mechanism 20 to the output shaft 4 side by deceleration control of the rotation speed n. At this time, the sun gear 5, the planetary gear 7, and the internal gear 6 are
Each rotates in the arrow direction shown by the arrow in FIG.
Then, when the rotation speed n of the small motor 16 becomes 0 (that is, when the rotation speed p of the internal gear 6 becomes 0).
Then, the rotation speed x of the output shaft 4 completely reaches the rated rotation speed.

Therefore, in the above-described power transmission device of the present invention, the switch is turned on when the prime mover 1 is not loaded and is idling at the rated rotation speed at the time of start-up. The current can be prevented. Further, in the above-described apparatus of the present invention, if a variable speed motor is used as the small motor 16 and the rotation speed of the variable speed motor is arbitrarily selected,
It can function as a continuously variable transmission. The present invention described above is not limited to the tunnel excavator described above, but can be widely applied to similar power transmission devices in which a large load is applied at startup.

[0021]

As described above, the device of the present invention allows the internal gear of the planetary gear mechanism provided between the prime mover and the driven part as a speed change part to be rotatable and has a self-locking function on the internal gear. With connecting the worm gear mechanism and connecting the worm gear mechanism to the small motor that rotates in the direction to release the self-locking function, when starting the prime mover after rotating the small motor at startup,
In order to increase the rotation speed of the output shaft of the planetary gear mechanism from 0 to the rated rotation speed while keeping the self-lock of the worm gear mechanism released by the rotation of the small motor,
It becomes possible to prevent the rush current to the prime mover with only a simple mechanical mechanism. Further, in the above startup device, when the small motor is a variable speed motor, the planetary gear mechanism can function as a continuously variable transmission by arbitrarily changing the rotation speed.

[Brief description of drawings]

FIG. 1 is a schematic view showing an example of a power transmission device provided with a starting device of the present invention.

FIG. 2 is a schematic diagram showing a relationship between a worm gear mechanism provided in the apparatus of FIG. 1 and a small motor.

3 is a schematic view of the planetary gear mechanism provided in the device of FIG. 1 as viewed from the axial direction.

[Explanation of symbols]

1 prime mover 20 planetary gear mechanism 30 driven part 2 output shaft (of prime mover) 3 input shaft of 3 (planetary gear mechanism) 4 output shaft of (planetary gear mechanism) 5 sun gear 6 internal gear 7 planetary gear 12 speed increaser 13 worm Gear mechanism 14 Worm wheel 15 Worm 16 Small motor 17 Output shaft (of small motor) 19 Brake

Claims (2)

(57) [Claims] 1. A power transmission device in which an output shaft of a prime mover is connected to a driven part through a speed change part composed of a planetary gear mechanism, wherein an inner gear of the planetary gear mechanism is rotatable and self-locked to the inner gear. A starting device for a power transmission device, which is connected to a worm wheel side of a worm gear mechanism having a function and further connected to a worm side to a small motor which rotates in a direction to release the self-locking function. 2. The starting device for a power transmission device according to claim 1, wherein a variable speed motor is used as the small-sized motor, and the planetary gear mechanism functions as a continuously variable transmission according to a speed change of the variable speed motor.