JPH02130224A - Auxiliary machinery driving device - Google Patents

Abstract

PURPOSE:To enable torque of high rotation and within a given range of number of revolutions to be output independently of the increase or decrease of the engine speed by connecting an auxiliary machinery to the output shaft which is connected to the sun gear of a belt-type speed change mechanism. CONSTITUTION:The crankshaft 9 of an engine 8 is interlocked with the input shaft 4 of a belt-type speed change mechanism 2, and a supercharger 19 is connected with the output shaft 15 connected to a sun gear 24. Thereby, when the number of revolutions of the crankshaft 9 increases, the groove width of the input-shaft-side speed change pulley 6 in the belt-type speed change mechanism 2 is broadened, and reversely the groove width of an output-shaft-side speed change pulley 7 is narrowed; therefore the speed change mechanism 2 shifts to the speed reduction side. Accordingly, independently of the variation in the number of revolutions of the crankshaft 9, the number of revolutions within a given range is always output from an output shaft 5. Further, since the output shaft 5 is connected to the internal gear 12 or the carrier 13 of a planetary gear train 3, the speed is significantly increased by the planetary gear train 3, and high rotational torque is output from the sun gear 24.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to an auxiliary equipment drive device for driving auxiliary equipment of an automobile.

The auxiliary drive device of the present invention is particularly suitable for driving a supercharger using engine output as a power source.

(Prior art) Automotive auxiliary equipment, that is, loads other than the drive that rotates the wheels,
Specifically, a supercharger, a generator, a water pump, a compressor, etc. are driven by the rotational force of the engine's crankshaft as a power source.

Conventionally, power transmission between the crankshaft of this engine and the auxiliary equipment was carried out using a direct belt or ribbed belt.

However, in the above-mentioned power transmission, the rotational speed of the auxiliary machine fluctuates depending on the high or low rotational speed of the engine, and the auxiliary machine is not necessarily driven under optimal conditions. Therefore, the present applicant first automatically sets the reduction ratio to a small reduction ratio when the engine speed is low, and conversely to a large reduction ratio when the engine speed is high, so that the auxiliary equipment is always maintained at the optimal rotation speed. Disclosed a centrifugal thrust variable speed pulley that drives a
No. 666).

(Problems to be Solved by the Invention) However, although the centrifugal thrust type variable speed pulley described above has a good effect when used as an auxiliary machine to drive a compressor or a generator, it is not effective when used as an auxiliary machine to drive a supercharger. had difficulty in its application. That is, since a supercharger is often installed for the purpose of compensating for a lack of engine torque during sudden acceleration, it is necessary to operate at a relatively low engine speed. On the other hand, in order for a supercharger to fully demonstrate its capabilities, a rotation speed of 10,000 or more is required, and a speed increase ratio of well over 10 times the engine rotation speed is required. Ru.

However, it is impossible for the speed change pulley to bear such a large speed increase ratio due to space considerations, and there has been a desire for the development of a new accessory drive device based on the prior art. In view of the above circumstances, an object of the present invention is to propose an auxiliary drive device that can output rotational force at high rotation speed and within a constant rotation speed range, regardless of the increase or decrease in engine rotation speed.

(Means for Solving the Problems) The features of the present invention for achieving the above object are as follows:
This is an auxiliary drive device having a belt-type transmission mechanism and a planetary gear train, and the belt-type transmission mechanism is capable of changing groove widths of the manpower shaft and output shaft of the belt-type transmission mechanism, which are arranged at regular intervals. The planetary gear train has a pulley thrust mechanism that expands the groove width of the pulley on the human power shaft side and decreases the groove width of the pulley on the output shaft side as the engine speed increases. The output shaft of the belt-type transmission mechanism, which is composed of a positive gear, a planetary gear, and an internal gear, is connected to a carrier that connects the internal gear or the planetary gear, and the positive gear is located in an auxiliary drive device connected to the output shaft.

(Function) The auxiliary drive device of the present invention is used by interlocking the engine crankshaft with the human power shaft of the belt type transmission mechanism and connecting the auxiliary machine with the output shaft connected to the Taiyo gear.

The rotational force transmitted from the crankshaft is first input to the belt-type transmission mechanism. In this belt type transmission mechanism, as the rotation speed of the crankshaft increases, the groove width of the pulley on the input shaft side increases, and conversely, the groove width on the output shaft side decreases, so as the rotation speed of the crankshaft increases, the transmission mechanism shifts to the deceleration side. Therefore, regardless of fluctuations in the rotation speed of the crankshaft, a rotation speed within a certain range is always output from the output shaft of the belt type transmission mechanism.

Since the output shaft of the belt-type transmission mechanism is connected to the internal gear of the planetary gear train or the carrier of the planetary gear,
The speed is greatly increased by the planetary gear train, and a high-speed rotational force is output from the sun gear.

Further, by providing a brake on the carrier or the internal gear that can be switched to stop and release the rotation, it is possible to switch between driving and stopping the rotation of the output shaft of the accessory drive device.

(Example) Specific examples of the present invention will be further described below.

FIG. 1 is a mechanical diagram of an auxiliary drive device in a specific embodiment of the present invention, and FIG. 2 is a mechanical diagram of an auxiliary drive device in another embodiment of the present invention.

In FIG. 1, a portion (1) surrounded by a dashed line is an auxiliary drive device.

The auxiliary drive device (1) of this embodiment has a belt type transmission mechanism (
2) and a planetary gear train (3).

The belt type transmission mechanism (2) has an input shaft (4) and an output shaft (5) of the belt type transmission mechanism (2) arranged at a certain interval.
A manual shaft side speed change pulley (6) and an output shaft side speed change pulley (7) are provided between the two.

The speed change pulleys (6) and (7) themselves are not particularly different from known speed change pulleys, and a detailed explanation will be omitted, but the input shaft (4)
As the rotation speed of the engine (8) increases, that is, the rotation speed of the crankshaft (9) of the engine (8) increases, the groove width of the pulley increases on the input shaft side, and conversely, the groove width of the pulley decreases on the output shaft side. When the human power shaft (4) rotates at low speed, the belt (
10) engages with the pulley (6) at a portion where the pitch diameter is large, and engages at a portion where the pitch diameter is small on the -force output shaft (5) side.

Conversely, when the rotational speed of the input shaft (4) increases, the belt (10) engages with the speed change pulley (6) at the part where the pitch diameter is small on the input shaft side speed change pulley (6), and the output shaft side speed change occurs. In the pulley (7), the engagement occurs at the portion where the pitch diameter is large. As the pulley sheep thrust mechanism for enlarging or reducing the groove width of the pulley, various conventionally known means can be used, such as those using an electric motor, hydraulic pressure, pneumatic pressure, or using centrifugal force of a weight.

The planetary gear train (3) consists of a sun gear (24), two planetary gears (11) (11'), and an internal gear (12).

The above three types of gears are centered around the Taiyo gear (24) and the planetary gear (
11) (11°) revolves and is rotatable, and M
An internal gear (12) is provided on the outside of the star gear (11) (11'), and the sun gear (24) and the planet gear (11) fit together, and the planet gear (11) and the internal gear (12) fit together, respectively. ing.

Further, the planetary gears (11) (11') are interconnected by a drum-shaped carrier (13). Career (1
3), a belt brake (14) is arranged on the outside of the carrier (13) and can stop the rotation of the carrier (13).

The input shaft (4) of the belt type transmission mechanism (2) is protruded to the outside as an input shaft of the auxiliary drive device itself, and the output shaft of the belt type transmission mechanism (2) is integrally connected to the internal gear (12). Fixed. The auxiliary drive device (1) is attached to the planetary gear (3).
An output shaft (15) is provided. The input shaft of the auxiliary drive device of this embodiment, that is, the human power shaft (4
) is connected to an engine (8) to a crankshaft (9) via pulleys (16), (17) and a belt (18) in an increasing speed state, and an output shaft (15) is connected to a supercharger (19). ing. Also, the belt brake (14) is connected to the engine (
8) is set to stop the rotation of the carrier when the throttle opening reaches a certain value or more. With the above configuration, when the driver steps on the accelerator, that is, when the engine requires a large torque, the belt brake (14) closes and the rotation of the carrier is stopped, and the information is transmitted from the crankshaft to the internal gear (12) via the belt type transmission mechanism. The generated rotational force is transmitted to the output shaft (15) via the planetary gears (11) (11').
is transmitted. When the throttle opening is below a certain value, the belt brake (14) is released and the carrier (13
) idles and no rotational force is transmitted to the output shaft (15).

In the above embodiment, the belt type transmission mechanism (2) and the planetary gear train (3) connect the output shaft of the belt type transmission mechanism (2) to the internal gear of the planetary gear train (3), and connect the output shaft of the belt type transmission mechanism (2) to the internal gear of the planetary gear train (3). Although a brake is provided, the present invention is not limited to this, and as shown in Fig. 2, the output shaft (2) of the belt type transmission mechanism is connected to the carrier (22) of the planetary gear (21), and the internal gear (2) is connected to the carrier (22) of the planetary gear (21). The internal gear (23) can be rotated freely.
It is also possible to provide a brake (24) outside of 3).

(Effects) The auxiliary drive device of the present invention combines a belt-type transmission mechanism and a planetary gear train, and uses the planetary gear train to increase the speed of the rotational force that has been regulated to a rotation speed within a certain range by the belt-type transmission mechanism. A certain range of high-speed rotational force can be obtained.

Further, since the present invention uses a planetary gear train as a speed increasing means, it has the effect of being able to reduce the size of the external shape, and can be installed even in a narrow installation space.

[Brief explanation of drawings]

FIG. 1 is a mechanical diagram of an auxiliary drive device in a specific embodiment of the present invention, and FIG. 2 is a mechanical diagram of an auxiliary drive device in another embodiment of the present invention. (1)...Auxiliary drive device (2)...Belt type transmission mechanism (3)...Planetary gear train (4)...Input shaft of belt type transmission mechanism (5) (20)
... Output shaft of belt type transmission mechanism (8) ... Engine (9) ... Crankshaft (10) ... Taiyo gear (11) (11°) (21) ... Planetary gear ( 12)(
23)...Internal gear (13) (22)...Carrier (14) (24)...Belt brake (15)...
・Output shaft

Claims (4)

[Claims] 1. An auxiliary drive device having a belt-type transmission mechanism and a planetary gear train, the belt-type transmission mechanism being capable of changing the groove width of the input shaft and output shaft of the belt-type transmission mechanism, which are arranged at regular intervals. The planetary gear train has a pulley thrust mechanism that expands the groove width of the pulley on the input shaft side and decreases the groove width of the pulley on the output shaft side as the engine speed increases. An auxiliary drive device comprising a positive gear, a planetary gear, and an internal gear, and an output shaft of the belt type transmission mechanism is connected to the internal gear, and a positive gear is connected to the output shaft. 2. 2. The auxiliary drive device according to claim 1, wherein the planetary gears are each connected by a carrier, and the carrier is provided with a brake. 3. An auxiliary drive device having a belt-type transmission mechanism and a planetary gear train, the belt-type transmission mechanism being capable of changing the groove width of the input shaft and output shaft of the belt-type transmission mechanism, which are arranged at regular intervals. A pulley is provided, and the groove width of the pulley on the input shaft side is expanded as the engine speed increases,
It has a pulley sheep thrust mechanism that reduces the groove width of the pulley on the output shaft side, and the planetary gear train consists of a Taiyo gear, a planetary gear, a planetary gear carrier, and an internal gear, and the output shaft of the belt type transmission mechanism is a planetary gear. An auxiliary drive device characterized in that it is connected to a carrier, and the Taiyo gear is connected to an output shaft. 4. 4. The auxiliary drive device according to claim 3, wherein the internal gear is provided with a brake.