JP2004084772A - Belt transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To stably maintain the belt tensile force in a loose side span of a belt 8 when applying the belt tensile force by pushing spans 8a, 8b provided on both sides of an auxiliary pulley 4 with tension pulleys 29, 30, in a belt transmission system A which is formed by wrapping the auxiliary belt 8 between a crank pulley 2 of an engine and the auxiliary pulley 4 provided on a rotary shaft 3 of an auxiliary module working as a starter motor when starting the engine and working as a generator after starting the engine, cranks with the auxiliary module when starting the engine, and drives the auxiliary module for power generation with the engine after starting the engine. <P>SOLUTION: Base ends of a pair of arms 16, 17 pivotally supporting tension pulleys 29, 30 at each tip are supported freely to rock at separate positions P1, P2, and the tips of both the arms 16, 17 are connected by a tensile spring 36, and the tension pulleys 29, 30 push the belt spans 8a, 8b to energize both the arms 16, 17 to turn so that the belt tensile force is generated. A belt wrapping angle of the tension pulley for pushing the tensile side span of the belt 8 is formed smaller than that of the tension pulley for pushing the loose side span. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a belt transmission device in which a transmission belt is wound between pulleys, and particularly to a technical field related to a belt transmission device in which a belt span between pulleys reverses to a tight side and a loose side.
[0002]
[Prior art]
Conventionally, as a starting device for an engine, a starter motor connected to a crankshaft of the engine at the time of starting the engine is provided, and the operation of the starter motor cranks and starts the engine. The starter motor startup noise may be loud and cause noise.
[0003]
Therefore, in order to not only ensure quietness at the time of starting, but also to improve the fuel efficiency of the engine, an auxiliary machine module with the function of a starter motor is provided as an auxiliary machine of the engine, and this auxiliary machine module is For example, a belt transmission system is constructed by driving and connecting the engine crankshaft with an accessory belt together with other accessories such as a compressor for an air conditioner and a hydraulic pump for a power steering device. When the engine module and other auxiliary equipment are driven to rotate, idling is stopped to stop the engine to improve fuel economy.When the engine is restarted from the stopped state, the auxiliary equipment module is used as a starter motor. Function, and this accessory module allows the engine By rotating the shaft cranking, it is known to start the engine.
[0004]
In such a belt transmission system, the belt tension of both sides of the accessory belt wound around the accessory pulley of the accessory module was reversed before and after the engine was started, and was on the tight side before the engine was started. One of the spans changes to the loose side after the start, and the other span, which was on the loose side before the start, changes to the tight side. For this reason, if one auto tensioner is used and the belt tension is adjusted by pressing the loose side span of the belt with the auto tensioner, when the loose side span changes to the tight side span, the auto tensioner is turned on the tight side. The tension is adjusted in the span, and the belt tension in the loose side span is reduced. In the worst case, the belt is loosened and slip occurs, which may cause a transmission failure.
[0005]
Thus, even if the driving state of the pulley changes and the tension side and the loose side of the belt span on both sides of the pulley reverse, the tension on the loose side is not reduced. And a pair of arms pivotally supported at one base of each fixed body at each base end, and a belt rotatably supported at the distal end of each arm and wound around a pulley. There has been proposed an automatic tensioner including a pair of tension pulleys that generate a belt tension by pressing both spans from the outer surface side.
[0006]
In this proposal, when the tension pulley is pushed back from the tension side span of the belt and the tension side arm supporting the pulley rotates to a fixed state where it cannot be further rotated, the tension side arm rotates. In response to the rotation of the tension side arm to the fixed state, the loose side arm supporting the tension pulley of the loose side span of the belt is also rotated in cooperation with the tension side arm, and the loose side span is rotated. The tension is adjusted.
[0007]
[Problems to be solved by the invention]
However, in the case of the proposed example, when the two arms are integrated, the loose arm in the loose span does not rotate when the tight arm in the tight span is fixed. Therefore, when the tension of the loose side span is reduced and the driving load on the driven auxiliary machine or the starting load of the engine is large, the loose side tension cannot be maintained at a high level, and the transmission may still be in a poor transmission state.
[0008]
On the other hand, if both arms are separate and can be independently rotated, and both arms are biased by a spring, the above-mentioned problem does not occur, and the tension on the loose side span of the belt is reduced. It can be adjusted to maintain that tension.
[0009]
However, on the other hand, in the fixed state of the tension arm, the load direction received from the belt via the pulley is the arm length direction, and the arm length direction and the rotation direction of the arm are substantially orthogonal, so that It is difficult to reliably stop the rotation of the tension side arm by the tension of the belt. As a result, when a tension fluctuation on the belt tension side occurs due to any rotation fluctuation, the tension arm is rotated and not fixed, and the belt tension on the loose side span cannot be stably held.
[0010]
An object of the present invention is to provide a belt transmission device that uses a pair of swingable arms as a tensioner as described above, and adjusts the tension by pressing the span of the belt with a tension pulley that is pivotally supported at its tip. On the other hand, by specifying the layout of each arm with respect to the belt span, it is possible to stably maintain the belt tension on the loose side span of the belt.
[0011]
[Means for Solving the Problems]
In order to achieve the above object, according to the present invention, a pair of arms supporting a tension pulley for pressing the belt spans on both sides of the pulley are supported at different positions, and the two arms are connected by urging means. By rotating each arm so that the tension pulley presses the belt span, the belt winding angle of the tension pulley on the tension side span of the belt is smaller than that of the tension pulley on the loose side span. The tension of the loose side span is adjusted.
[0012]
Specifically, according to the first aspect of the present invention, at least two pulleys, a first and a second pulley, and a transmission belt wound between the two pulleys are provided, and one of the first and the second pulleys is driven. The present invention is directed to a belt transmission that switches between a pulley state and a drive pulley state.
[0013]
An auto-tensioner for adjusting the tension of the belt is provided. The auto-tensioner has a pair of arms independently swingably supported at respective base ends at positions separated from each other, and a tip of each arm. A tension pulley rotatably supported by a portion and capable of pressing both spans of the belt between the two pulleys; and a tension pulley connected between the two arms. The tension pulley presses the span of the belt to generate belt tension. Biasing means for rotating and urging both arms so that the tension winding pulley pressing the tension side span of both the belts has a smaller belt winding angle than the tension pulley pressing the loose side span. It is characterized by having such a configuration.
[0014]
According to the above configuration, the pair of arms are independently and swingably supported at their base ends at separate positions, and the arms are connected to each other by the urging means. Since the arm is rotationally urged so that the pulley presses the belt span to generate belt tension, of the belt span between the first and second pulleys, the pulley on the tension side span is pushed from the belt. In return, when the tension arm supporting the pulley rotates, the pulley at the tip of the loose arm connected to the tension arm via the urging means responds accordingly. As a result, the belt winding angle of the tension pulley that presses the tension side span of the belt becomes smaller than that of the tension pulley that presses the loose side span.
[0015]
Since the winding angle of the tension side span to the tension pulley is smaller than the winding angle of the loose side span to the tension pulley, when the transmission load of the belt transmission device occurs, the tension side The belt tension of the tension side span increases to infinity with the decrease of the winding angle to zero, and the drive system is determined only by determining the biasing force of the biasing means for obtaining the belt tension of the loose side span. It will be established. In other words, the sharing of the belt tension by the biasing means is effected by the tension pulley on the loose side, and only the tension on the loose side is set by the biasing force of the biasing means, and between the first and second pulleys. Even if the driving direction is reversed, the belt tension is always adjusted on the loose side span to ensure the transmission state with a low belt tension. And belt noise can be prevented.
[0016]
In addition, since the movement trajectory of the two tension pulleys is an elliptical trajectory when the two pulleys are combined, the movement of the tension pulleys is defined as a circular motion as compared with the case where both tension pulleys are connected to each other at the axial position by the urging means. By making the direction of the axial load generated from the span tension different from the direction of movement of the tension pulley, the movement distance of the tension pulley can be reduced, and while using a low spring constant biasing means with little change in tension due to free length tolerance. The same effect as when using the biasing means having a high spring constant can be obtained. Thus, it is not necessary to use a large urging means to increase the spring rigidity in order to reduce the deformation of the urging means when an excessive load torque is generated, and it is possible to use a compact urging means.
[0017]
In addition, the effective tension of the belt greatly differs depending on the difference in the load direction between the first and second pulleys, and when the two tension pulleys are directly connected to each other by the urging means, the minimum required of the larger load is required. Although it is necessary to adjust the urging force to the tension, two arms having different support positions are provided as in the present invention. By changing the support positions of these arms, the urging characteristics in the driving direction can be set arbitrarily. It is only necessary to set the lowest appropriate biasing force, and it is possible to reduce the fuel consumption due to the loss of the axial force of the engine and improve the life of the device.
[0018]
In the invention of claim 2, the tension pulley is capable of pressing both spans of the belt from the outer surface side, and the urging means is a tension spring extended between the arms. According to the third aspect of the present invention, the tension pulley can press both spans of the belt from the inner surface side, and the biasing means is a compression spring compressed between the arms. According to these inventions, a desirable configuration of the arm layout and the urging means can be obtained.
[0019]
A fourth aspect of the present invention is characterized in that a damping means for damping the rotation of the arm is provided. In this case, the rotation of each arm can be attenuated, the transient vibration and the like can be prevented, and stable belt running can be ensured.
[0020]
According to the fifth aspect of the present invention, the arm is rotatably supported on the shaft by the boss, and the damping means is a damper member interposed between the boss of the arm and the shaft. According to the invention of claim 6, the first slide member is swingable on one arm, and the second slide member is slidably engaged with the first slide member in the length direction on the other arm. , And the damping means attenuates the slide of both slide members. According to the configurations of the present invention, preferable damping means can be easily obtained.
[0021]
In the invention according to claim 7, in the belt transmission according to claim 1 or 4, the first pulley is a crank pulley provided on an output shaft of the engine. The second pulley serves as a starter motor when the engine is started, and is an auxiliary pulley provided on a rotating shaft of an auxiliary module which becomes an auxiliary after the start. Further, the belt is an accessory belt wound around at least between the accessory pulley and the crank pulley. When the engine is started, the crank pulley is rotated by the accessory module. It is configured to drive the machine pulley.
[0022]
With this configuration, at the time of starting the engine, the crank pulley of the engine is rotationally driven via the accessory belt by the accessory module serving as a starter motor, and the engine is cranked and started. Then, the auxiliary pulley is rotationally driven by the crank pulley via the auxiliary belt, and the auxiliary module is operated.
[0023]
Also in this case, similarly to the first aspect of the invention, it is only necessary to set the tension of the loose side span by the urging force of the urging means, and it is possible to stably maintain the tension of the loose side span, and to reduce the belt tension. Generation of slip and belt noise can be prevented.
[0024]
In the invention according to claim 8, the accessory module is a motor generator that becomes a generator after the engine is started. As a result, the starter motor is used when the engine is started, and the tension of the loose side span is stably maintained in the belt drive device for driving the auxiliary machine including the auxiliary machine module which becomes the generator after the start. Can be.
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
(Embodiment 1)
FIG. 1 shows an overall configuration of a belt transmission A according to a first embodiment of the present invention. This belt transmission A is used as an auxiliary belt start system for an engine mounted on a vehicle. This system drives the auxiliary equipment by the engine in an operating state after the start of the engine (not shown), and cranks the engine by some of the auxiliary equipment when the engine is started after an idling stop or the like. It is used to start.
[0026]
That is, in FIG. 1, reference numeral 1 denotes a crankshaft (CS: crankshaft) as an output shaft of the engine, and 2 denotes a crank pulley as a first pulley which is integrally attached to the crankshaft 1. Reference numeral 3 denotes an accessory module rotating shaft provided on an accessory module (not shown) on the upper side of the crankshaft 1; is there. Reference numeral 5 denotes an idler shaft disposed at substantially the same height as the crankshaft 1, and reference numeral 6 denotes an idler pulley rotatably provided on the idler shaft 5. These pulleys 2, 4, and 6 are all clocks shown in FIG. Rotate around.
[0027]
The crankshaft 1, the accessory module rotating shaft 3, and the idler shaft 5 are arranged in parallel with each other, for example, in a layout located at the apex of a substantially triangle. The accessory module includes a motor generator (MG) having two functions of a motor and a generator. The accessory module serves as a starter motor when the engine is started, while the generator ( Alternator).
[0028]
The crank pulley 2, the auxiliary pulley 4, and the idler pulley 6 are all V-ribbed pulleys, and an auxiliary belt 8 made of a V-ribbed belt as a transmission belt is wound between these pulleys 2, 4, and 6. When the engine is started, the auxiliary module is operated as a starter motor, the auxiliary pulley 4 is switched to a drive pulley, and the crank pulley 2 is switched to a driven pulley. While rotating the crank pulley 2 to crank and start the engine, in an operating state after the engine is started, the auxiliary module functions as a generator, and conversely, the crank pulley 2 is used as a drive pulley. The auxiliary pulley 4 is switched to a driven pulley, and the auxiliary pulley 4 is rotated by the crank pulley 2. Driven by driving the auxiliary equipment module, and is adapted to power generation.
[0029]
An auto-tensioner 11 for adjusting the tension of the accessory belt 8 is provided between the crank pulley 21 and the idler pulley 6 and the accessory pulley 4. As shown in enlarged detail in FIGS. 2 to 5, the auto tensioner 11 includes first and second round rod-shaped spindles 12 and 12, each of which is disposed at a first and second pivot position P1, P2. 13 is provided. The first and second pivot positions P1 and P2 are located apart from each other, and the first pivot position P1 is, for example, a center position between the crankshaft 1 and the idler shaft 5 and a position of the accessory module rotation shaft 3. The second pivot position P2 is set on one side (the right side in FIG. 1) of the vertical plane passing therethrough, and on the other side (the left side in FIG. 1) of the same plane at the same height and at the same distance from the plane. Have been. At the base end side of each of the spindles 12 and 13, a substantially triangular plate-like mounting bracket portion 12a, 13a having a plurality of bolt insertion holes 14, 14,... Each spindle 12, 13 is attached to the engine main body (not shown) by a mounting bracket 12a, 13a. At the pivot positions P1 and P2.
[0030]
The first spindle 12 is provided with a first arm 16 and the second spindle 12 is provided with a second arm 17 having the same arm length as the first arm 16 so as to be swingable at a boss portion 18 at a base end thereof. Supported. Specifically, as shown in FIGS. 3 to 5 for the first arm 16 (the second arm 17 will be described with the same reference numerals), the boss portions 18 of the arms 16 and 17 are concentric with each other. It has a double cylindrical structure having an inner cylinder 19 and an outer cylinder 20 provided. A through hole 21 is formed in the bottom of the inner cylinder 19, and the spindles 12 and 13 are mounted on the inner cylinder 19 from the tip side. The inner cylinder 19 and the spindles 12 and 13 are fitted via a resin sliding bearing 22 as a damper member. The front ends of the spindles 12 and 13 protrude from the through holes 21, and a front plate 23 is fixed to the front ends by caulking or the like, and a boss 18 is provided between the front plate 23 and the bottom wall of the boss 18. A ring-shaped resin-made thrust washer 24 as a damper member that slides on the bottom surface is interposed, and the first bearing 25 and the thrust washer 24 constitute first damping means 25. Damping resistance is applied to the rotation of each of the arms 16 and 17 by friction to attenuate the rotation. The first damping means 25 can be provided on only one of the first and second arms 16 and 17.
[0031]
Each of the arms 16 and 17 protrudes radially from the bottom side of the outer cylinder 20 of the boss portion 18. A first tension pulley 29 is provided at the tip of the first arm 16, and a tip tension pulley 29 is provided at the tip of the second arm 17. The second tension pulleys 30 are rotatably supported. The supporting structures of the tension pulleys 29 and 30 are the same. Here, the first tension pulley 29 will be described, and the second tension pulley 30 will be assigned the same reference numeral and detailed description will be omitted.
[0032]
That is, a shaft 27 extending parallel to the spindle 12 is formed at the tip of each of the arms 16 and 17, and tension pulleys 29 and 30 are rotatably supported around the shaft 27 via a bearing 28. I have. A screw hole 26 is formed in the center of the shaft 27 so as to penetrate from the front to the back of the arms 16 and 17. Numeral 31 designates a circular disc-shaped bearing retainer. Bolts 32 passing through the bearing retainer 31 are inserted to the intermediate positions of the screw holes 26 and screwed together, so that the tension pulleys 29 and 30 are attached to the tips of the arms 16 and 17. It is retained and supported.
[0033]
Each of the first and second tension pulleys 29 and 30 is a flat pulley, and two tension pulleys 29 and 30 are provided between the crank pulley 2 and the auxiliary pulley 4 to enter and exit the auxiliary pulley 4. The belt spans 8a and 8b, specifically, the first span 8a on the right side in FIG. 1 without passing through the idler pulley 6 and the second span 8b on the left side in FIG. Tension is generated.
[0034]
It is desirable to use an angular bearing (shown in the figure) or a parallel bearing for each of the bearings 28 at the tips of the arms 16 and 17. It is preferable that the tension pulleys 29 and 30 be made of a lightweight material such as a press-molded product or a nylon molded product containing a thermosetting resin or a reinforcing fiber.
[0035]
Further, a tension spring 36 as an urging means is connected in an extended state between the distal ends of the arms 16 and 17 of the auto tensioner 11 (in detail, the end of the tension spring 36 is connected to each spring guide described later). 38, 39), the two arms 16, 17 are brought close to each other by the tension spring 36, that is, the first arm 16 is rotated clockwise in FIGS. 1 and 2, the first and second tension pulleys 29 and 30 respectively cause the first and second spans 8a and 8a of the belt 8 to rotate. 8b so as to generate a belt tension, and as shown in FIGS. 7B and 7C, of the first and second spans 8a, 8b, the span 8b (or 8a) which is the tight side is set. Tension pull to press The belt winding angle θ2 (or θ1) of 30 (or 29) becomes smaller than the belt winding angle θ1 (or θ2) of the tension pulley 29 (or 30) pressing the span 8a (or 8b) on the loose side. Like that.
[0036]
That is, a bottomed cylindrical first spring guide 38 as a first slide member is provided on the back surface of the distal end of the first arm 16, and a diameter larger than that of the first spring guide 38 on the back surface of the distal end of the second arm 17. A bottomed cylindrical second spring guide 39 as a second slide member is supported rotatably around the shaft 27 at the bottom. The mounting structure of the spring guides 38 and 39 to the distal ends of the arms 16 and 17 is the same, and the case of the first arm 16 will be described with reference to FIGS. 3 and 4 (the same reference numeral is assigned to the second arm 17). The spring guides 38 and 39 are formed integrally with a cylindrical spring engaging portion 42 extending in the diametrical direction at the inner bottom thereof, and a bolt insertion hole 40 penetrates through the spring engaging portion 42. A support bolt 41 is rotatably inserted into the bolt insertion hole 40. Then, the threaded ends of the support bolts 41 are inserted into the screw holes 26 at the ends of the arms 16 and 17 from the back side to the middle and screwed together, so that the spring guides 38 and 39 are supported by the support bolts 41 at the bottom. And is rotatably supported.
[0037]
Further, the open end of the first spring guide 38 is slidably fitted to the open end of the second spring guide 39, and the two spring guides 38 and 39 are integrated into a hollow cylindrical shape. When the distal ends of the first and second spring guides 16 and 17 are separated from each other and the distance between the two ends changes, the open ends of the first spring guide 38 slide within the open ends of the second spring guides 39, so that the arms 16 and 17 are moved. To absorb the distance between the tips. The tension spring 36 is fitted inside the spring guides 38 and 39, and one end of the tension spring 36 is attached to a spring engagement portion 42 at the inner bottom of the first spring guide 38. The other ends of the tension springs 36 are locked by spring locking portions 42 of the second spring guide 39, respectively.
[0038]
Further, a second damping means 45 for damping the rotation of each of the arms 16 and 17 is provided. That is, a plurality of (four in the illustrated example) ring grooves 46, 46,... Are arranged on the inner peripheral surface of the open end of the second spring guide 39 on the large diameter side in the longitudinal direction of the second spring guide 39. A ring-shaped damper 47 made of resin is fitted in each of the ring grooves 46. When the spring guides 38 and 39 slide and expand and contract, each of the dampers 47 is moved to the first position. The first spring guide 38 is slidably contacted with the outer peripheral surface of the open end to attenuate the sliding movement.
[0039]
In FIG. 2, reference numeral 49 denotes a stopper pin which is engaged in a state of penetrating in the radial direction between the walls at the distal end portions of both spring guides 38 and 39. When the auto tensioner 11 is assembled, the stopper pin 49 is previously set. By restricting the expansion and contraction slide of the spring guides 38 and 39 in the engaged state, and by pulling out the stopper pin 39 after the assembly, the spring force of the tension spring 36 is actuated to allow the spring guides 38 and 39 to expand and contract. The tension pulleys 29 and 30 press the belt spans 8a and 8b.
[0040]
Therefore, in the above embodiment, the auto tensioner 11 is arranged between the crank pulley 2, the auxiliary pulley 4, and the idler pulley 6, and the pair of arms 16, 17 of the auto tensioner 11 are pivoted at positions P1, P2 separated from each other. Each of the arms 16 and 17 is independently swingably supported at its base end, and the ends of both arms 16 and 17 are connected by a tension spring 36 so that the arms 16 and 17 are rotationally biased. The two tension pulleys 29, 30 at the tips of the arms 16, 17 press the spans 8a, 8b of the accessory belt 8 on both sides of the accessory pulley 4 from the outer surface to apply belt tension.
[0041]
Specifically, for example, when the engine enters an idling state at a signal waiting of a vehicle or the like in order to improve the fuel efficiency of the engine, the idling stop is performed, the engine stops, and the engine enters a no-load state. In the stopped state of the engine, as shown in FIGS. 6A and 7A, the belt tensions T1 and T2 of the first and second spans 8a and 8b of the accessory belt 8 are the same (T1 = T2). ), The winding angle θ1 of the first span 8a around the first tension pulley 29 and the winding angle θ2 of the second span 8b around the second tension pulley 30 are the same (θ1 = θ2). , 17 have the same pulley pressing force F1, F2 for pressing the tension pulleys 29, 30 by the belt spans 8a, 8b (F1 = F2).
[0042]
Thereafter, when the engine is started, the auxiliary module is energized and operates as a starter motor, and the auxiliary pulley 4 on the rotating shaft 3 of the auxiliary module becomes a drive pulley, and the crank on the crankshaft 1 of the engine is driven. The pulley 2 becomes a driven pulley, and the crank pulley 2 is rotationally driven via the accessory belt 8 by the operation of the accessory module, whereby the crankshaft 1 of the engine is cranked and the engine is started.
[0043]
In the starting cranking state of the engine, as shown in FIG. 6B, of the two spans 8 a and 8 b of the belt 8 between the crank pulley 2 and the auxiliary pulley 4, the second through the idler pulley 6. The two spans 8b (the left side span in FIG. 1) become the tension side spans, and the first spans 8a (the right side span in FIG. 1) which do not pass through the idler pulley 6 become the loose side spans. The second tension pulley 30 is pushed back from the second span 8b, and the second arm 17 (tension side arm) supporting the second tension pulley 30 rotates around the second spindle 13 as shown in FIGS. It rotates in the direction of rotation. With the rotation of the second arm 17, the first arm 16 (the loose side arm) whose distal end is connected to the distal end of the second arm 17 by a tension spring 36 is also driven by the contraction spring force of the tension spring 36. Accordingly, the first tension pulley 29 at the tip of the first arm 16 presses the first span 8 a, which is the loose side span of the belt 8. Thus, the tension of the loose side span 8a is adjusted and held.
[0044]
At this time, as shown in FIG. 7 (b), the belt tension T2 of the second span 8b of the accessory belt 8 becomes larger than the belt tension T1 of the first span 8a (T2> T1), and the first tension pulley 29 Is larger than the winding angle θ2 of the second span 8b with respect to the second tension pulley 30 (θ1> θ2), and the tension pulleys 29 and 30 at the tips of the arms 16 and 17 are moved. The pulley pressing forces F1 and F2 pressed by the belt spans 8a and 8b are equal to each other (F1 = F2). When the starting load is the maximum, as shown in FIG. 7C, the belt tension T2 of the second span 8b becomes larger than the belt tension T1 of the first span 8a (T2≫T1), and the second tension pulley Further, the winding angle θ2 of the second span 8b with respect to 30 is further changed to be close to zero.
[0045]
When the engine is started and is in an operating state, in the operating state, the auxiliary module functions as a generator, and conversely, the crank pulley 2 switches to the driving pulley and the auxiliary pulley 4 switches to the driven pulley. The auxiliary pulley 4 is rotated by the crank pulley 2 to drive the auxiliary module, and power is generated by the auxiliary module.
[0046]
In this operating state of the engine, of the two belt spans 8a and 8b between the crank pulley 2 and the auxiliary pulley 4, the first span 8a not passing through the idler pulley 6 becomes the tighter span and the idler pulley 6 becomes The passing second spans 8b become loose side spans, respectively, and the first tension pulley 29 is pushed back from the first span 8a which has become the tight side span, and the first arm supporting the first tension pulley 29 is provided. 16 (tension side arm) rotates around the first spindle 12 in the counterclockwise direction in FIG. With the rotation of the first arm 16, the second arm 17 (the loose arm) connected by the tension spring 36 also rotates in the same direction, and accordingly, the second tension pulley 30 at the tip of the second arm 17. Presses the second span 8b, which is the loose side span of the belt 8. Thereby, the tension of the loose side span 8b is adjusted and held.
[0047]
At this time, the belt tension T1 of the first span 8a of the accessory belt 8 becomes larger than the belt tension T2 of the second span 8b (T1> T2), and the winding angle θ2 of the second span 8b around the second tension pulley 30 is set. Is larger than the winding angle θ1 of the first span 8a with respect to the first tension pulley 29 (θ2> θ1), and further, the belt pulleys 8a and 8b push the tension pulleys 29 and 30 at the tips of the arms 16 and 17 with the pulley pressing force. F1 and F2 are the same (F1 = F2). When the load on the accessory module is maximized, the belt tension T1 of the first span 8a becomes larger than the belt tension T2 of the second span 8b (T1≫T2), and the first span 8a with respect to the first tension pulley 29 is set. Is changed so that the winding angle θ1 becomes close to zero.
[0048]
As described above, of the spans 8a and 8b of the belt 8 between the crank pulley 2 and the auxiliary pulley 4, the pulley 30 (or 29) of the tension side is pushed back from the belt 8, and the pulley 30 (or 29) is pushed. When the tension arm 17 (or 16) supporting the arm rotates, the loose arm 16 (or 17) connected to the tension arm 17 (or 16) via the tension spring 36 accordingly. Since the pulley 29 (or 30) at the front end presses the loose side span of the belt 8, the belt winding angle θ2 (or θ1) of the tension pulley 30 (or 29) pressing the tight side span of the belt 8 decreases. , Which is smaller than the tension pulley 29 (or 30) which presses the pulley 30 (or 29) when the transmission load of the belt transmission A occurs. As the winding angle θ2 (or θ1) decreases to zero, the tension T2 (or T1) of the tension side span increases to infinity, and the tension for obtaining the belt tension T1 (or T2) of the loose side span is obtained. The drive system is established only by determining the urging force of the spring 36. That is, the belt tension is allotted by the tension spring 36 by the tension pulley 29 (or 30) on the loose side, and only the tension on the loose side is set by the urging force of the tension spring 36. Even when the driving direction is reversed between the auxiliary pulleys 4, the belt tension is always adjusted at the loose side span to ensure the transmission state with a low belt tension, and the loose side span tension is stably maintained. In addition, it is possible to prevent the occurrence of slip and belt noise due to a decrease in belt tension.
[0049]
Further, the movement trajectory of the two tension pulleys 29 and 30 is an elliptical trajectory when the two pulleys 29 and 30 are combined together, so that the tension pulleys 29 and 30 are tensioned as compared with the case where both tension pulleys 29 and 30 are connected to each other by a tension spring at the axial position. By making the movement of the pulleys 29 and 30 a circular motion and making the direction of the axial load generated from the span tension different from the direction of the movement of the tension pulleys 29 and 30, the moving distance of the tension pulleys 29 and 30 can be reduced. The same effect as that obtained by using a tension spring having a high spring constant while using the tension spring 36 having a low spring constant with little change in tension due to the long tolerance can be obtained. Thus, it is not necessary to use a large tension spring 36 to increase the spring stiffness in order to reduce the deformation of the tension spring 36 when an excessive load torque is generated, so that a compact tension spring 36 can be used.
[0050]
Also, the tension on the loose side span increases according to the load so as to satisfy the minimum required belt tension for the load, so that the belt tension can be properly adjusted according to the load of the accessory module to improve the fuel efficiency of the engine and the auxiliary equipment. The life of each bearing of the rotating shaft 3 and the crankshaft 1 of the module can be extended.
[0051]
Further, since the first and second damping means 25 and 45 for damping the rotation of the arms 16 and 17 are provided, the rotation of the arms 16 and 17 in the first damping means 25 It is attenuated by the frictional resistance of the thrust washer 24. On the other hand, in the second damping means 45, when the tension spring 36 expands and contracts with the rotation of the arms 16 and 17, and the spring guides 38 and 39 slide accordingly, the spring guides 38 and 39 slide. The slide receives resistance by the dampers 47, 47,..., And the rotation of each arm 16, 17 is attenuated. By these two damping means 25 and 45, the transient vibration and the like are prevented, and stable belt running can be ensured.
[0052]
Further, since the tension spring 36 is interposed between the first and second arms 16 and 17, even if the crank pulley 2 serving as a driving pulley has a large rotation fluctuation due to the periodic combustion of the engine during operation of the engine. The fluctuation of the rotation can be absorbed by the swing of the first arm 16 in the first span 8a, which is the tension side span of the belt 8, and the fluctuation load due to the rotation fluctuation of the crank pulley 2 is rotated by the rotation of the first arm 16 as the tension side arm. Thus, the steady load of the auxiliary pulley 4 as the driven pulley can be separately adjusted by the rotation of the second arm 17 as the slack side arm.
[0053]
(Embodiment 2)
FIG. 8 shows a second embodiment of the present invention (in the following embodiments, the same parts as those in FIGS. 1 to 7 are denoted by the same reference numerals, and detailed description thereof is omitted). The pivot positions P1 and P2 of the two arms 16 and 17 are changed.
[0054]
That is, in this embodiment, the first and second pivot positions P1 and P2 are, for example, both sides of a vertical plane passing through the center position between the crankshaft 1 and the idler shaft 5 and the position of the accessory module rotation shaft 3. Are arranged at the same height, but the distance between the first pivot position P1 and the plane in the vertical direction is set to be larger than the distance between the second pivot positions P2. The lengths of both arms 16 and 17 are the same. Other configurations are the same as those of the first embodiment.
[0055]
Therefore, in this embodiment, the tension of the second span 8b, which is the tension side span, and the tension of the first span 8a, which is the loose side span, at the time of starting the engine are both increased compared to the first embodiment. Can be. During the operation after the engine is started, the tension of the first span 8a, which is the tension side span, and the tension of the second span 8b, which is the loose side span, are smaller than those in the first embodiment.
[0056]
Further, a hub load formed by the length direction (center line) of each of the arms 16 and 17 and the direction of pulley pressing forces F1 and F2 pressing the tension pulleys 29 and 30 at the tips of the arms 16 and 17 by the belt spans 8a and 8b. Regarding the angles θh1 and θh2, in the first embodiment, the hub load angles θh1 and θh2 can be the same in the no-load state when the engine is stopped. Thus, the hub load angle θh2 on the second tension pulley 30 side can be made larger than the hub load angle θh1 (<θh2) on the first tension pulley 29 side.
[0057]
From these facts, not only can the belt tension be arbitrarily set in the same manner as in the first embodiment, but also in this embodiment, the belt tension at the start of the engine and at the time of operation after the start is based on the initial state (no load state). As an asymmetric characteristic.
[0058]
(Embodiment 3)
9 to 11 show the third embodiment, in which the first damping means 25 for damping the rotation of the arm 16 in the auto tensioner 11 is changed.
[0059]
That is, in this embodiment, the torsion coil spring 52 is housed between the inner cylinder 19 and the outer cylinder 20 in the boss portion 18 of the first arm 16 so as to surround the inner cylinder 19. As shown in FIG. 10, one end of the torsion coil spring 52 is provided in a cutout 53 provided in the mounting bracket 12 a of the first spindle 12, and the other end is provided in a spring stopper hole opened in the outer cylinder 20 of the boss 18. The first arm 16 is rotationally urged, for example, clockwise in FIG. 9 by the torsion spring force of the torsion coil spring 52.
[0060]
A resin spring support 56 as a damper member is interposed between the torsion coil spring 52 and the inner cylinder 19. The spring support 56 includes a cylindrical portion 56 a located around the inner cylinder 19, A flange portion 56b protruding radially outward from one end of the cylindrical portion 56a and slidingly contacting the mounting bracket 12a of the spindle 12; When the diameter of the torsion coil spring 52 expands or contracts with the rotation of the first arm 16, the rotation of the arm 16 is attenuated while changing the pressing force of the spring support 56 against the inner cylinder 19. I have.
[0061]
Therefore, in the case of this embodiment, since the torsion coil spring 52 and the spring support 56 are provided as the first damping means 25 for attenuating the rotation of the arm 16, the tension spring 36 is provided with the rotation of the arm 16. When expanded or contracted, the rotation of each arm 16 is further effectively attenuated. In this way, in cooperation with the first damping means 45, the transient vibration and the like can be prevented, and a more stable belt running can be secured.
[0062]
(Other embodiments)
In each of the above embodiments, an accessory belt starting system (belt transmission device A) for an engine in which an accessory belt 8 is wound around the crank pulley 2, the accessory pulley 4, and the idler pulley 6, and the accessory is one, will be described. In addition, a compressor for an air conditioner, a hydraulic pump for a power steering device, a water pump, and the like may be provided as auxiliary components of the engine, and these may be driven via the accessory belt 8. Good.
[0063]
In each of the above embodiments, the tension spring 36 is connected between the distal ends of the arms 16 and 17, but may be connected to an intermediate portion of the arms 16 and 17 other than the boss 18. Further, in the above embodiment, both the spans 8a, 8b of the belt 8 can be pressed from the outer surface side by the tension pulleys 29, 30, and the urging means is the tension spring 36 extended between the arms 16, 17. Further, both spans 8a and 8b of the belt 8 can be pressed from the inner surface side by the tension pulleys 16 and 17, and the biasing means can use a compression spring compressed between the arms 16 and 17.
[0064]
Furthermore, in each of the embodiments described above, the present invention is applied to the auxiliary belt starting system of the engine. However, the present invention can be applied to other belt transmissions, and includes at least two pulleys and a winding between these pulleys. Any belt transmission device that includes a transmission belt that is hung and that switches between a state in which one of the pulleys is a drive pulley and a state in which the other is a drive pulley is sufficient.
[0065]
【Example】
Next, a specific embodiment will be described. Example 1 is a belt transmission device A (see FIG. 1) having the configuration of the first embodiment, and includes a crank pulley 2 and an idler pulley 6 having a pulley diameter of 150 mm, and an auxiliary pulley 4 having a pulley diameter of 60 mm. Prepared, each layout was set on two-dimensional XY coordinates. The axis of the crank pulley 2 is on the coordinates (0 mm, 0 mm), the axis of the idler pulley 6 is on the coordinates (-300 mm, 0 mm), and the axis of the auxiliary pulley 4 is on the X coordinate (-150 mm). The pulleys 2, 4, and 6 were wound around a V-ribbed belt 8 (specification "RT2700") having a circumference of 1740 mm and 10 ribs. Further, the first pivot position P1 of the auto tensioner 11 is set to coordinates (−49 mm, 295 mm), the second pivot position P2 is set to coordinates (−251 mm, 295 mm), and the respective lengths of the first and second arms 16, 17 are set. Each of them has the same 75 mm, and a first tension pulley 29 having a pulley diameter of 75 mm is supported at the tip of the first arm 16, and a second tension pulley 30 having the same pulley diameter of 75 mm is supported at the tip of the second arm 17. A tension spring 36 having a spring length of 200 mm and a spring constant of 7.45 N / mm was stretched between the distal ends of the 16 and 17.
[0066]
On the other hand, the belt transmission A of Embodiment 2 (see FIG. 8) is Example 2, the first pivot position P1 of the auto tensioner 11 is coordinates (−49 mm, 295 mm), and the second pivot position P2 is coordinates (−). 251 mm, 295 mm). Others are the same as the first embodiment.
[0067]
Then, the engine is started from the initial state of no load and the tension of the second span 8b of the belt 8 is higher than the first span 8a, and conversely, the tension of the first span 8a is higher than that of the second span 8b. The relationship between the effective tension Tt−Ts, which is the difference between the tight span tension Tt and the loose span tension Ts, and both span tensions Tt and Ts was examined for the operating state of the engine that became high. The result of FIG. 12 and the result of FIG. 13 for Example 2 were obtained.
[0068]
From these results, it can be seen that in each of Example 1 and Example 2, the tension of the slack side spans 8a and 8b of the belt 8 is always a plus value, and the belt tension can be arbitrarily set. .
[0069]
Further, the relationship between the effective tension Tt-Ts and the hub load angles θh1 and θh2 (see FIG. 8) was examined for Examples 1 and 2, and the relationship of FIG. Fifteen relationships were each obtained. From this result, by changing the pivot positions P1 and P2, which are the fulcrums of the arms 16 and 17, as in the second embodiment, the belt tension at the time of starting the engine and at the time of operation after the starting is changed from the initial state (no load state). It can be seen that an asymmetric characteristic can be set as a reference.
[0070]
【The invention's effect】
As described above, according to the first aspect of the present invention, there are provided at least two pulleys, the first and second pulleys, and the transmission belt wound around the two pulleys, and one of the first and second pulleys is provided. For a belt transmission device that switches between a driving pulley state and a driving pulley state, a tension pulley that presses a belt span on both sides of the pulley as an auto tensioner that adjusts belt tension is supported. A pair of arms are swingably supported at positions separated from each other, and both arms are connected by urging means, and both arms are rotated so that the tension pulley presses the belt span and belt tension is generated. The tension wrap of the tension pulley that presses the tension side span of the belt is smaller than that of the tension pulley that presses the loose side span. All that is necessary is to apply the belt tension distribution by the biasing means to the tension pulleys on the loose side and to set the tension on the loose side by the biasing force of the biasing means. Even if is reversed, the belt tension is always adjusted on the loose side span to ensure the transmission state with low belt tension, and the loose side span tension is stably maintained to reduce slip and belt noise due to a decrease in belt tension. Occurrence can be prevented. Also, since the movement trajectory of the two tension pulleys is an elliptical trajectory when the two pulleys are combined, the moving distance of the tension pulley is reduced by making the direction of the axial load generated from the span tension different from the direction of the movement of the tension pulley. It is possible to obtain the same effect as using a biasing means having a high spring constant while using a biasing means having a low spring constant with a small change in tension due to free length tolerance, and using a compact biasing means. be able to. Further, by changing the support position of the arm, it is possible to set the lowest appropriate biasing force, and it is possible to reduce the fuel consumption due to the loss of the axial force of the engine and improve the life of the equipment.
[0071]
According to the second aspect of the present invention, the belt span is pressed from the outer surface side by the tension pulley, and the urging means is a tension spring extended between the arms. Further, in the invention of claim 3, the tension pulley presses the belt span from the inner surface side, and the urging means is a compression spring compressed between the arms. According to these inventions, a desirable configuration of the arm layout and the urging means can be obtained.
[0072]
According to the fourth aspect of the present invention, the provision of the damping means for damping the rotation of the arm prevents transient vibration of each arm and the like, thereby ensuring stable belt running.
[0073]
According to the fifth aspect of the invention, the arm is rotatably supported on the shaft by the boss, and the damping means is a damper member interposed between the boss of the arm and the shaft. According to the invention of claim 6, the first slide member is pivotally movable on one arm, and the second slide member is slidably engaged with the first slide member in the length direction on the other arm. The supporting and attenuating means attenuates the sliding of both slide members. According to the configurations of the present invention, preferable damping means can be easily obtained.
[0074]
According to the invention of claim 7, the first pulley is a crank pulley provided on the output shaft of the engine, and the second pulley is a starter motor when the engine is started, and is an auxiliary machine module that is an auxiliary machine after the start. The auxiliary pulley provided on the rotating shaft, the belt is at least an auxiliary belt wound around between the auxiliary pulley and the crank pulley, while rotating the crank pulley by the auxiliary module when starting the engine, After the start, the auxiliary pulley was driven by the crank pulley. In the invention according to claim 8, the accessory module is a motor generator that becomes a generator after the engine is started. According to these inventions, when the engine is started, the engine is cranked and started by the accessory module via the accessory belt, and after the engine is started, the engine is rotated by the crank pulley via the accessory belt. In the belt drive for driving auxiliary equipment that drives the module, it is only necessary to set the tension of the loose side span by the urging force of the urging means, and it is possible to stably maintain the tension of the loose side span and reduce the belt tension. This can prevent slip and belt noise from occurring.
[Brief description of the drawings]
FIG. 1 is a diagram schematically illustrating an overall configuration of a belt transmission according to a first embodiment of the present invention.
FIG. 2 is an enlarged front view showing the auto tensioner partially broken away.
FIG. 3 is an enlarged side view showing the auto tensioner partially broken away.
FIG. 4 is an enlarged rear view showing the auto tensioner partially cut away.
FIG. 5 is a sectional view taken along line VV of FIG. 2;
FIG. 6 is a view corresponding to FIG. 1 showing a movement when the load changes from a no-load state to a maximum load state when the engine is started by the accessory module.
FIG. 7 is an explanatory diagram showing a relationship between tension of each span of a belt and a winding angle around a tension pulley.
FIG. 8 is a diagram corresponding to FIG. 1 showing a second embodiment of the present invention.
FIG. 9 is a diagram corresponding to FIG. 2, showing a third embodiment of the present invention.
FIG. 10 is a diagram corresponding to FIG. 3, showing a third embodiment.
FIG. 11 is a diagram corresponding to FIG. 5, showing the third embodiment.
FIG. 12 is a characteristic diagram showing a relationship between the effective tension of the belt span and the belt tension of the tension side span and the loose side span in Example 1.
FIG. 13 is a diagram corresponding to FIG. 12, showing the relationship between the effective tension of the belt span and the belt tension of the tension side span and the loose side span in Example 2.
FIG. 14 is a characteristic diagram showing a relationship between a hub load angle of each pulley and an effective tension of a belt span in the first embodiment.
FIG. 15 is a diagram corresponding to FIG. 14 showing a relationship between the effective tension of the belt span and the hub load angle of each pulley in the second embodiment.
[Explanation of symbols]
A belt transmission
1 crankshaft
2 Crank pulley (first pulley)
3 Auxiliary module rotation axis
4 Auxiliary pulley (second pulley)
8 Auxiliary equipment belt (transmission belt)
8a 1st span
8b 2nd span
11 Auto tensioner
12 1st spindle (shaft)
13 Second spindle (shaft)
16 1st arm
17 Second arm
18 Boss
22 Sliding bearing (damper member)
24 Thrust washer (damper member)
25 First damping means
29 1st tension pulley
30 2nd tension pulley
36 Tension spring (biasing means)
38 1st spring guide (1st slide member)
39 second spring guide (second slide member)
45 Second damping means
47 Damper
52 torsion coil spring
56 Spring support (damper member)
P1 1st pivot position
P2 2nd pivot position
θ1, θ2 Belt wrap angle

Claims (8)

At least first and second two pulleys;
A transmission belt wound between the two pulleys,
A belt transmission device that switches between a state in which one of the first or second pulley becomes a driving pulley and a state in which the other becomes a driving pulley,
Equipped with an auto tensioner to adjust the tension of the belt,
The auto-tensioner includes a pair of arms independently and oscillatably supported at respective base ends at positions separated from each other;
A tension pulley rotatably supported at the tip of each of the arms and capable of pressing both spans of the belt between the pulleys;
Biasing means connected between the two arms, the tension pulley presses the span of the belt, and biases both the arms so as to generate a belt tension;
A belt transmission device characterized in that a belt winding angle of a tension pulley that presses a tension side span among both spans of the belt is smaller than a tension pulley that presses a loose side span. The belt transmission according to claim 1,
The tension pulley is capable of pressing both spans of the belt from the outer surface,
The urging means is a tension spring extended between the arms. The belt transmission according to claim 1,
The tension pulley is capable of pressing both spans of the belt from the inside,
The urging means is a compression spring compressed between the arms. The belt transmission according to any one of claims 1 to 3,
A belt transmission device comprising damping means for damping rotation of an arm. The belt transmission according to claim 4,
The arm is rotatably supported on the shaft by the boss,
The damping means is a damper member interposed between a boss portion and a shaft portion of the arm, wherein the belt transmission device is provided. The belt transmission according to claim 4,
A first slide member is supported on one arm, and a second slide member that slidably engages with the first slide member in the length direction is swingably supported on the other arm, respectively.
The belt transmission device is characterized in that the damping means attenuates the slide of both slide members. The belt transmission according to claim 1 or 4,
The first pulley is a crank pulley provided on the output shaft of the engine,
The second pulley is an auxiliary pulley provided on a rotating shaft of an auxiliary module serving as an auxiliary machine after the start while the starter motor is used when the engine is started,
The belt is an accessory belt wound around at least the accessory pulley and the crank pulley,
A belt transmission device configured to rotate a crank pulley by an accessory module when the engine is started, and to drive the accessory pulley by the crank pulley after the engine is started. The belt transmission according to claim 7,
A belt transmission device, wherein the auxiliary module is a motor generator that becomes a generator after the engine is started.

Images