JP4917783B2 - Auto tensioner - Google Patents

Description

  The present invention mainly relates to an auto tensioner that maintains a constant tension of a chain or a toothed belt that drives a camshaft.

  In general, in a chain transmission for driving a camshaft that spans a chain between a sprocket attached to the end of the crankshaft and a sprocket attached to the end of the camshaft, the chain can be swung on the slack side of the chain. The chain guide is contacted, and the tension of the auto tensioner is applied to the chain guide to keep the chain tension constant.

  As an auto tensioner employed in the chain transmission device, one described in Patent Document 1 has been conventionally known. In this auto tensioner, a nut member having a rod at the tip is slidably inserted into the body, and a serrated male screw formed on the outer periphery of the bolt member is formed on a serrated female screw formed on the inner periphery of the nut member. The above-mentioned nut member is projected outward by a return spring built into the body, and the pushing force applied from the chain to the rod of the nut member via the chain guide is sawtooth-shaped. The nut member is received by the pressure flank of the screw to prevent the nut member from moving backward, and when the pushing force is greater than the pushing force of the return spring, the nut member is rotated to a position where the pushing force and the spring force of the return spring are balanced. While moving backward, the chain tension is kept constant.

Further, when the chain is slack, the nut member is moved forward by the pressing force of the return spring to absorb the slack of the chain.
Japanese Utility Model Publication No. 64-41755

  By the way, the conventional auto tensioner is an assembly in which a tip of a rod provided on a nut member is brought into contact with a chain guide supported so as to be swingable. When the deviation occurs, a rotational force is applied to the nut member.

  In addition, the chain guide is a swingable support, and in order to absorb the vibration of the chain by the swinging of the chain guide, a rotational moment is applied to the nut member with which the rod at the end abuts the chain guide. The rotational moment acts directly on the screw engaging portions of the nut member and the bolt member.

  Here, when a rotational force is applied to the nut member, the nut member moves in the axial direction while rotating, and when the chain is tensioned, the resistance force that suppresses the vibration of the chain is reduced, and the sawtooth screw The operating characteristics cannot be exhibited effectively, and the chain tension cannot be kept constant.

  Further, if the rotational moment applied to the nut member directly acts on the saw-toothed screw, there is a possibility that the saw-toothed screw portion is bitten and the nut member does not move.

  An object of the present invention is to provide an automatic tensioner that maintains a constant chain tension with a serrated screw, even if a rotational force or rotational moment is applied by contact with a swingable chain guide. The rotation moment is not applied to the serrated thread so that a stable operation can be obtained at all times, and the slackness of the chain can be absorbed well.

In order to solve the above problems, in the present invention, a housing in which a cylinder chamber having one end opened is formed, a nut member incorporated in the cylinder chamber of the housing, and a female screw on the inner periphery of the nut member. The rod member includes an engaging male screw on the outer periphery of the rear end portion, and a return spring that imparts outward protrusion to the rod member. The rod member is loaded with the spring force of the return spring. A push rod that is movable in the axial direction and an adjustment screw that is coaxially arranged with the push rod and that has a male screw on the outer periphery, and the push rod is provided at the rear end of the cylinder and has an inner diameter of the cylinder chamber A sliding member that can slide along the surface and the mating surface of the cylinder chamber, and a push rod provided on the open end side of the cylinder chamber Slidably supported at two points of the fitting surface of the slidably supporting the guide member and the push rod, the loaded spring force of the return spring to the slide member, for biasing the adjusting screw to the push rod A spring is provided, and the female screw of the nut member and the male screw of the adjusting screw are serrated screws whose flank angle of the pressure side flank receiving the pushing force applied to the adjusting screw is larger than the flank angle of the play side flank, A configuration is adopted in which a passage is formed in at least one of the adjustment screws so as to communicate the internal space formed in the back portion of the adjustment screw inside the nut member and the external space outside the nut member.

  The auto tensioner configured as described above is assembled so that the tip of the push rod comes into contact with the swingable chain guide. If slack occurs in the chain in the assembled state, the push rod moves forward by pressing the return spring, and the chain guide is pressed against the chain to absorb the slack in the chain. Further, the adjustment screw advances while rotating by the pressure of the spring and comes into contact with the rear end of the push rod. At this time, since the volume of the internal space formed inside the nut member is enlarged and the pressure is reduced, the lubricating oil in the external space formed outside the nut member flows into the internal space from the passage and is adjusted. The screw moves smoothly to a position where it abuts against the rear end of the push rod, and absorbs the slack of the chain quickly.

  Further, when the chain is tensioned and a pushing force is applied from the chain to the push rod via the chain guide, the pushing force is supported by the pressure side flank of the serrated screw, and the push rod does not move backward. When the pushing force is larger than the spring force of the return spring, the adjusting screw moves backward to a position where the pushing force and the spring force are balanced to keep the chain tension constant.

  When adjusting the chain tension as described above, if the chain guide swings, the contact portion between the chain guide and the push rod is displaced, and a rotational moment is applied to the push rod. At this time, since the push rod and the adjusting screw are separated from each other at the opposed end faces, no rotation moment is applied to the adjusting screw, and the screw engaging portion of the female screw and the male screw is engaged. There is no inconvenience.

Furthermore , a slide member that can slide along the inner diameter surface of the cylinder chamber is provided at the rear end portion of the push rod located in the cylinder chamber, and a guide member that slidably supports the push rod is provided at the opening of the cylinder chamber. Because the rotational moment loaded on the push rod can be received at two places, the slide member and the mating surface of the cylinder chamber, and the mating surface of the guide member and the push rod, the push rod can be pivoted according to the chain tension change. It can be moved smoothly in the direction, and an auto tensioner excellent in responsiveness can be obtained.

Further, in the auto tensioner that guides the movement of the push rod by the slide member and the guide member, the guide member is provided on the opening end side of the cylinder chamber from the sealing member for sealing the lubricating oil provided in the opening portion of the cylinder chamber. Thus, the seal member can be prevented from being detached by the guide member, so that it is not necessary to incorporate a retaining member such as a retaining ring for retaining the seal member.

  When the auto tensioner as described above is assembled, the eccentric position with respect to the center of the tip surface of the push rod may come into contact with the chain guide due to an assembly error or the like. At this time, a rotational force is applied to the push rod by the swing of the chain guide, but the push rod and the adjusting screw are separated and arranged on the same axis, so that the adjusting screw is not loaded with the rotational force. . For this reason, there is no inconvenience that the adjusting screw rotates and moves in the axial direction. When the chain is tensioned, the resistance force that suppresses the vibration of the chain is prevented from decreasing, and the operating characteristics of the sawtooth screw are effectively exhibited. Can be made.

  Here, if at least one of the rear end surface of the push rod and the front end surface of the adjusting screw is a spherical surface, it is possible to more reliably prevent the rotational force from being transmitted from the push rod to the adjusting screw.

  As described above, the rod member that applies adjustment force to the chain guide is divided into the push rod and adjustment screw, so that even if rotational force or rotational moment is applied from the chain guide to the push rod, these rotational forces are applied. And the rotation moment is not transmitted to the adjusting screw, and when the chain is tensioned, the resistance force that suppresses the vibration of the chain is reduced, and the occurrence of inconvenience such as the biting of the serrated screw part is prevented, The chain tension can always be kept constant.

  In addition, a passage that connects the inner space inside the nut member and the outer space outside is formed in at least one of the nut member and the adjustment screw, so that the adjustment screw rotates toward the rear end of the push rod by the spring. When moving forward, the lubricating oil in the external space flows from the passage into the internal space. For this reason, there is no inconvenience that the internal space becomes negative pressure and hinders the forward movement of the adjustment screw, and the slack of the chain can be immediately absorbed by the adjustment screw and the push rod, and the followability is good. An auto tensioner can be obtained.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 shows a tension adjusting device for a camshaft drive chain. As shown in the figure, a chain 5 is spanned between a sprocket 2 attached to the end of the crankshaft 1 and a sprocket 4 attached to the end of the camshaft 3, and a chain guide is connected to the slack side of the chain 5. 6 is provided.

  The chain guide 6 can swing around a shaft 7 provided at the lower end thereof. The chain guide 6 is pressed against the chain 5 by an adjusting force loaded from the auto tensioner 10.

  As shown in FIG. 2, the auto tensioner 10 has a housing 11, and a cylinder chamber 12 having one end opened is formed in the housing 11.

  A nut member 13 is incorporated in the cylinder chamber 12, and a female screw 14 is formed on the inner periphery of the nut member 13. In addition, a rod member 15 and a return spring 16 that imparts outward protrusion to the rod member 15 are incorporated in the cylinder chamber 12.

  The rod member 15 is divided into a push rod 15a and an adjusting screw 15b. The push rod 15a slidably passes through a seal member 17 such as an oil seal that seals the opening of the cylinder chamber 12, and the cylinder A slide member 18 slidable along the inner diameter surface of the cylinder chamber 12 is provided at the rear end located in the chamber 12, and the pressing force of the return spring 16 is loaded on the slide member 18.

  On the other hand, a ring-shaped guide member 19 is provided in the opening of the cylinder chamber 12 from the seal member 17 to the opening end side of the cylinder chamber 12, and the push rod 15 a is slidably supported by the inner diameter surface of the guide member 19. Has been.

  The adjusting screw 15 b has a male screw 20 on the outer periphery, and the male screw 20 is engaged with the female screw 14 of the nut member 13. The screw engaging portion of the male screw 20 and the female screw 14 and the sliding surface between the slide member 18 and the cylinder chamber 12 are lubricated by the lubricating oil sealed in the cylinder chamber 12.

  The adjustment screw 15b is formed with a spring accommodating recess 21 that opens at its rear end surface. A spring 22 and a spring seat 23 are assembled between the closed end surface of the spring accommodating recess 21 and the closed end surface of the cylinder chamber 12, and the spring A spherical surface 23 a formed at the tip of the sheet 23 is in contact with the closed end surface of the spring accommodating recess 21.

  The spring 22 urges the adjusting screw 15b toward the push rod 15a, and by this urging, the spherical surface 24a at the front end of the protruding shaft portion 24 provided on the front end surface of the adjusting screw 15b is pressed against the rear end surface of the push rod 15a. It has been.

  As shown in FIG. 3, the threads of the female screw 14 formed on the inner periphery of the nut member 13 and the male screw 20 formed on the outer periphery of the adjusting screw 15b are pressures that receive a pressing force when the adjusting screw 15b is pressed. The flank angle of the side flank 25 has a sawtooth shape larger than the flank angle of the play side flank 26, and a lead angle that moves in the axial direction while the adjusting screw 15b is rotated by the pressing force of the spring 22 is provided on the sawtooth thread. ing.

  As shown in FIGS. 2 and 3, an inner space 28 formed on the back of the adjusting screw 15 b inside the nut member 13 and an outer space 29 provided on the outer side of the nut member 13 are provided at the tip of the adjusting screw 15 b. Is formed.

  The chain tension adjusting device shown in the embodiment has the above-described structure, and when the engine is driven, the chain 5 vibrates due to torque fluctuations caused by the rotation of the cam shaft 3, and the slack side chain of the chain 5 is slackened. Then, the push rod 15a moves outward by the pressing force of the return spring 16 to press the chain guide 6, and the slack of the chain 5 is absorbed by the pressing.

  When the push rod 15a moves outward, the adjusting screw 15b is rotated by the pressing force of the spring 22 while moving forward toward the push rod 15a, and the spherical surface 24a at the tip of the projecting shaft portion 24 is the rear end surface of the push rod 15a. Abut.

  At this time, the volume in the internal space 28 formed at the back portion of the adjusting screw 15b increases and the pressure decreases, so that the lubricating oil in the external space 29 flows into the internal space 28 from the passage 30.

  Therefore, there is no inconvenience that the internal space 28 has a negative pressure and the forward movement of the adjusting screw 15b is inhibited, and the adjusting screw 15b moves forward smoothly and absorbs the slack of the chain 5 immediately. Even when the chain 5 vibrates at a high frequency, the slack of the chain 5 is absorbed quickly.

  On the other hand, when the tension of the slack side chain of the chain 5 increases and a pushing force is applied from the chain 5 to the push rod 15a via the chain guide 6, the pushing force is also applied to the adjusting screw 15b. Therefore, the pressure side flank 25 of the female screw 14 of the nut member 13 and the male screw 20 of the adjusting screw 15b are in close contact with each other, and the pressing force is received by the pressure side flank 25 that is in close contact.

  When the pressing force is stronger than the pressing force of the return spring 16, slip occurs on the contact surface of the pressure side flank 25 that is in close contact with each other, and the adjusting screw 15 b slowly moves to a position where the pressing force and the pressing force of the return spring 16 are balanced. The chain 5 moves backward while rotating to keep the tension of the chain 5 constant.

  Here, since the chain guide 6 to which the adjusting force of the auto tensioner 10 is loaded is supported so as to be swingable about the shaft 7, when the pushing force is loaded from the chain guide 6 to the push rod 15a, the push rod A rotational moment is applied to 15a.

  At this time, the slide member 18 provided at the rear end of the push rod 15a is slidable along the inner diameter surface of the cylinder chamber 12, and the guide member 19 provided at the opening of the cylinder chamber 12 is a push rod. Since the slide rod 15a is slidably supported, the rotational moment applied to the push rod 15a is supported at two locations: the fitting surface of the cylinder chamber 12 and the slide member 18 and the fitting surface of the push rod 15a and the guide member 19. Will be.

  Therefore, no rotational moment is applied to the adjusting screw 15b, and there is no inconvenience that the screw engaging portion of the female screw 14 and the male screw 20 is caught.

  When the auto tensioner 10 is assembled, the eccentric position of the push rod 15a with respect to the center of the tip surface may be abutted against the chain guide 6 due to an attachment error or the like. At this time, a rotational force is applied to the push rod 15a by the swinging of the chain guide 6. However, the push rod 15a and the adjusting screw 15b are arranged coaxially, and the protruding shaft portion 24 of the adjusting screw 15b. Since the tip spherical surface 24a is in point contact with the rear end surface of the push rod 15a, the rotational force is not applied to the adjusting screw 15b.

  For this reason, there is no inconvenience that the adjusting screw 15b rotates and moves in the axial direction, and at the time of tension of the chain 5, it is possible to prevent a decrease in the frictional resistance force at the serrated screw portion that suppresses the vibration of the chain 5, The operating characteristics of the serrated screw can be effectively exhibited.

  In the example shown in FIG. 3, the rear end surface of the push rod 15a is a flat surface, and the spherical surface 24a at the tip of the protruding shaft portion 24 of the adjusting screw 15b is brought into contact with the rear end surface. The tip surface of the portion 24 may be a flat surface, and the spherical surface 27 may be provided at the rear end of the push rod 15a.

  Further, in the example shown in FIG. 3, the passage 30 that communicates the internal space 28 and the external space 29 of the nut member 13 is provided at the tip of the adjustment screw 15b. However, as shown in FIG. A passage 31 made of a hole penetrating from the diameter surface to the inner diameter surface may be formed. Alternatively, as shown in FIG. 5, a passage 32 made of an axial groove for dividing the female screw 14 of the nut member 13 in the circumferential direction is formed. It may be formed. Furthermore, although omitted in the drawing, a passage formed of an axial groove that divides the male screw 20 in the circumferential direction may be formed on the outer periphery of the adjusting screw 15b.

  As shown in FIG. 5, when the axial groove 32 that divides the female screw 14 of the nut 13 in the circumferential direction is formed, when a pressing force is applied to the adjusting screw 15b, the pressure side flank 25 between the female screw 14 and the male screw 20 is provided. Since the oil film formed in this way can be pushed into the groove 32 in the axial direction, it is possible to prevent the frictional resistance from being reduced due to the oil film interposed therebetween.

Schematic of a chain tension adjusting device employing an auto tensioner according to the present invention Longitudinal front view of the auto tensioner according to the present invention Sectional view showing the adjustment screw assembly Sectional drawing which shows the other example of the channel | path which connects the internal space and external space of a nut member Sectional drawing which shows the further another example of the channel | path which connects the internal space and external space of a nut member

Explanation of symbols

11 Housing 12 Cylinder chamber 13 Nut member 14 Female screw 15 Rod member 15a Push rod 15b Adjust screw 16 Return spring 18 Slide member 19 Guide member 20 Male screw 24a Spherical surface 25 Pressure side flank 26 Play side flank 27 Spherical surface 28 Internal space 29 External space 30 Passage 31 passage 32 passage

Claims (3)

A rod having a cylinder chamber in which one end is opened, a nut member incorporated in the cylinder chamber of the housing, and a rod having a male screw on the outer periphery of the rear end portion that is engaged with a female screw on the inner periphery of the nut member A push rod that includes a member and a return spring that imparts outward protrusion to the rod member, and the rod member is movable in the axial direction to which the spring force of the return spring is loaded, and the push rod The push rod is provided at the rear end portion thereof and is slidable along the inner diameter surface of the cylinder chamber and is fitted to the cylinder chamber. A guide member and a push lock which are provided on the mating surface and on the opening end side of the cylinder chamber and slidably support the push rod. Slidably supported at two points of the fitting surface of said slide member the spring force of the return spring loaded in, provided a spring for biasing the adjusting screw to the push rod, and the internal thread of the nut member The male screw of the adjustment screw is a serrated screw whose flank angle of the pressure side flank receiving the pushing force applied to the adjustment screw is larger than the flank angle of the play side flank, and at least one of the nut member and the adjustment screw has a nut member An auto tensioner in which a passage that communicates an internal space formed on the back of the adjusting screw and an external space outside the nut member is formed on the inside. The auto tensioner according to claim 1, wherein the guide member is provided closer to the opening end of the cylinder chamber than a sealing member for sealing a lubricant provided in the opening of the cylinder chamber. The auto tensioner according to claim 1 or 2, wherein one of the rear end surface of the push rod and the front end surface of the adjusting screw is a spherical surface.

Images