JP2001032896A - Tensioner and method for stabilizing operation of the tensioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ensure operation smoothness at the initial stage of a use of an apparatus by a method wherein a film formed of a solid lubricant is formed at the slide part of each of the parts of an apparatus, in a tensioner formed such that first and second shaft members threadedly engaged with each other are contained in a case. SOLUTION: A tensioner to keep the tension of a timing belt, used in an engine, at a constant value is provided with first and second shaft members 3 and 4 threadedly engaged with each other by means of screws 3a and 4a, and the two members 3 and 4 are slidably supported in a case 2 by a shaft support member 7 and a bearing 9. Since the first shaft member 3 is rotationally energized through the force of a torsion spring 8 and rotation of the second shaft member 4 is constrained, the second shaft member 4 is axially moved. In this case, a film formed of a solid lubricant, for example, MoS2, is formed at the slide part of each of the parts of an apparatus, such as the screw parts 3a and 4a of the shaft members 3 and 4, and smoothness of operation is improved.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tensioner for maintaining a constant tension of a chain, a timing belt, and the like used for two-wheeled vehicles, four-wheeled vehicles, and the like.

[0002]

2. Description of the Related Art When a chain or a timing belt of an automobile or a motorcycle is stretched or loosened, for example, the tensioner pushes or pulls the chain or the timing belt in a certain direction to thereby adjust the tension. Is a device that keeps constant. Hereinafter, the structure of a typical tensioner will be described.

FIG. 3 is a view showing an example of a mounting layout of a tensioner attached to an engine body. The engine 50 includes an endless timing chain 53 between a pair of cam sprockets 51 and a crank sprocket 52.
Is run around. The tensioner 1 has a curved chain guide 10 that abuts and guides the timing chain 53, and the chain guide 10
1 is mounted so as to be swingable with a fulcrum. And
When the shaft member 4 that expands and contracts the tensioner 1 swings the chain guide 10, the timing chain 5
Adjust the tension of 3.

FIG. 4 is a longitudinal sectional view showing details of the tensioner 1 as an example shown in FIG. In the figure,
Inside the case 2, the first and second shaft members 3,
4 is assembled and inserted. The case 2 is attached to the engine body as shown in FIG. 3, and a flange 6 having an attachment hole 5 for attachment is formed to extend outward.

[0005] The first and second shaft members 3 and 4 are assembled by attaching an external thread 3 a to the outer peripheral surface of the first shaft member 3.
On the other hand, a female screw portion 4a is formed on the inner peripheral surface of the second shaft member 4, and these screw portions 3a, 4a are screwed together. The assembled first and second shaft members 3 and 4 are supported in the case 2 by fitting the rear end 3 c of the first shaft member 3 to the shaft receiving member 7. In the assembled state,
The first shaft member 3 is screwed into a substantially half portion on the front side, and a torsion spring 8 is externally inserted into a substantially half portion on the rear side.

The torsion spring 8 has one end locked to the first shaft member 3 and the other end locked to the case 2. Therefore, when the torsion spring 8 is assembled in a state where a predetermined torque is applied by torsion, the first shaft member 3 is rotated by the rotational urging force of the torsion spring 8.

The second shaft member 4 has a cylindrical shape, and a substantially half portion of the front side of the first shaft member 3 is inserted in a screwed state. The second shaft member 4 includes a bearing 9
It is supported by being inserted through. This bearing 9 is fixed to the tip of the case 2.

The bearing 9 has a sliding hole 9a having a substantially oval shape.
(See FIG. 1). The outer periphery of the second shaft member 4 is formed in the same shape as the sliding hole 9a.
Therefore, the second shaft member 4 is connected to the sliding hole 9 of the bearing 9.
The rotation of the second shaft member 4 is restricted by inserting the second shaft member 4.

With such a structure, even if the first shaft member 3 is rotated by the action of the rotational biasing force of the torsion spring 11, the second shaft member 4 screwed to the first shaft member 3 is used. Does not rotate. For this reason, the rotation urging force of the torsion spring 8 is converted into the propulsion force of the second shaft member via the rotation of the first shaft member 3, and the second shaft member 4 is rotated.
Will advance. As a result, the second shaft member 4 presses the timing chain through the chain guide 10 to apply a constant tension. The tensioner shown in FIGS. 3 and 4 is a push-acting type that operates in the direction of pushing the timing chain or the like, but is not particularly shown, but is a tension-acting type tensioner that operates in the direction of pulling the timing chain or the like. There is also.

In the screw type tensioner as described above, the second shaft member is pushed by an external input load input from a timing chain, a belt, or the like, and tries to retreat and pushes back. The tension operation is performed by the balancing action of the tensioner. by the way,
The operation smoothness (movability) of the screw-type tensioner that affects the balancing action of the tensioner refers to the degree of behavior of the tensioner with respect to the strength of the input load from the timing chain or the belt. Is determined mainly by the following factors (see FIG. 5; the tensioner 1 in FIG. 5 is the same as the tensioner 1 shown in FIG. 4).

Screw lead angle (°) If the lead angle A of the screw to which the first shaft member 3 and the second shaft member 4 are screwed is large, the operation smoothness is good (light), and if the lead angle A is small, the operation is good. Low smoothness (heavy). Contact diameter of rear end surface of shaft Rear end portion 3c of first shaft member 3 sliding with case 2
When the diameter of the rear end face is small, the working smoothness is good (light), and when the diameter is large, the working smoothness is low (heavy). Coefficient of friction of sliding part (μ) Each part on which each part of the device slides, that is, the sliding part between the second shaft member 4 and the bearing 9 or the first shaft member 3 and the second part
If the coefficient of friction of the screw portion with which the shaft member 4 is screwed and the sliding portion between the shaft receiving member 7 and the rear end portion 3c of the first shaft member 3 are low, the operation smoothness is good (light) and the friction is low. If the coefficient is high, the operation smoothness is low (heavy). The urging force of the torsion spring 8 is good (light) when the urging force of the torsion spring 8 is weak, and low (heavy) when the urging force is strong. It has the above relationship. Among them, the friction coefficient of the sliding surface generally tends to be high at the beginning of use of the device and tends to be low at the end of the product life. As a result, the operation smoothness of the tensioner fluctuates between the initial stage of using the device and the end of the endurance. By the way, as for, the change in the fluctuation of the operation smoothness until the end of the endurance can be handled as a very small change.

Here, the "return torque value (T)" which is an index indicating the operation smoothness (movability) will be described with reference to FIG. In the figure, the return torque value (T) is shown in FIG.
As shown in (1), a weight W having a predetermined weight is placed on the tip of the tensioner 1, a torque measuring instrument is inserted into a slit 3b formed at the rear end of the first shaft member 3, and the shaft is rotated at a constant rotation speed. The resistance torque at this time is called a return torque value.

[0013] Of the above factors,
,, The following relationship holds. Friction coefficient of each sliding part High ← → Low Return torque value Large ← → Small In addition, the following relationship exists between the return torque value and the operation smoothness. Operation smoothness Difficult to move (heavy) ← → Easy to move (good) Return torque value large ← → small That is, the following can be said. Good operation smoothness = small return torque Good operation smoothness = large return torque After that, the operation smoothness and weight are returned and the return torque value (= T)
Expressed by

FIG. 2 is a graph conceptually showing the transition of the return torque value from the beginning of use of the screw type tensioner to the end of the durability as compared with the conventional product. A conventional tensioner generally slides between steels (metals) whose sliding surfaces have been subjected to heat treatment or plating. In this case, FIG.
Follow the transition shown in In other words, the return torque value is maximum in the early stage of the use of the device, and has a characteristic that the amount of decrease after that is large. there were.

[0015]

As described above, in the conventional screw-type tensioner, the return torque value is maximum at the beginning of use of the device, and the amount of decrease in the torque value thereafter is large. There is a problem that the degree of freedom of design is narrowed due to the necessity of designing equipment. The present application has been made in view of the above problems, the return torque value is minimal at the beginning of the use of the device, the return torque value increases thereafter, and thereafter, quickly transition to a stable state, thereby, An object of the present invention is to provide a tensioner that can perform a stable tension operation and thus has a high degree of freedom in device design and a method of stabilizing the operation of the tensioner.

[0016]

According to the present invention, in order to solve the above-mentioned problems, according to the first and second aspects of the present invention, a first shaft member and a second shaft member screwed by a screw portion are provided. A spring for urging the first shaft member to rotate in one direction, and a sliding portion for slidably supporting the first shaft member and the second shaft member. And a case accommodating the second shaft member. The tensioner restrains the rotation of the second shaft member and converts the rotational urging force of the spring into a unidirectional propulsion force of the second shaft member. Forming a film of a solid lubricant on the screw portion and other sliding portions including the sliding portion, improving the operation smoothness in the initial stage of using the device and stabilizing the operation characteristics, the solid lubricant is Molybdenum Fluororesin, graphite-based, and tensioner consisting of one or a mixture of these phosphate coating.

According to the third and fourth aspects of the present invention, the first shaft member and the second shaft member screwed together by the screw portion, and the first shaft member are urged to rotate in one direction. And a case that has a sliding portion that slidably supports the first shaft member and the second shaft member and that houses the first shaft member and the second shaft member, A method for stabilizing the operation of a tensioner for restricting rotation of the second shaft member and converting the rotational urging force of the spring into a unidirectional propulsion force of the second shaft member, wherein the screw portion and the sliding portion are provided. A solid lubricant film is formed on other sliding parts, including, to improve the operation smoothness at the beginning of use of the equipment and to stabilize the operation characteristics, and the solid lubricant is made of molybdenum-based, fluororesin-based, graphite-based And either or operating method of stabilizing tensioner comprising a mixture of their phosphate coating.

According to the above configuration and method, the solid lubricant applied to the sliding surface reduces the friction torque of the sliding surface, so that the return torque value is minimized at the beginning of use of the device, and thereafter, the return torque is reduced. Stabilization of the torque value progresses quickly.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described with reference to the drawings. 1 are the bearing 9, the second shaft member 4, the first shaft member 3, and the shaft receiving member 7 of the screw-type tensioner 1 shown in FIGS. 4 and 5, but in the present invention, As shown in FIG. 1, the sliding portions of various parts of the apparatus including the female screw portion 4 a of the second shaft member 4 and the male screw portion 3 a of the second shaft member 3 are coated with a solid lubricant such as MoS _2. To form

The solid lubricant to be used is any of molybdenum-based such as MoS ₂ or the like, fluororesin-based such as PTFE, graphite-based, phosphate-based, or a mixture thereof, but is not limited thereto. Any material having good slidability can be used. In addition, the method of forming the film is based on the MoS ₂
In the case of PTFE or PTFE, it is mainly kneaded with a resin-based binder and applied and baked.

FIG. 2 is a graph showing the relationship between the operating time of the engine and the return torque of the tensioner. The input load from the engine was measured and reproduced and measured as an external input to a tensioner by a hydraulic vibrator. Graph line a is the measured value of the conventional product, and graph line b is the present invention.

In the screw type tensioner in which the solid lubricant such as MoS ₂ is applied and formed on the sliding surface, the solid lubricant is in contact with the solid lubricant in the initial stage of operation, and the return torque value shows the minimum value (see FIG. 2 x). Then, the wear of the solid lubricant proceeds (y in FIG. 2), and thereafter, when the operation is continued,
The metal of each part comes out of the face and shifts to contact between steel (metal) on the sliding surface (z in FIG. 2), and thereafter shows a stable return torque value. As described above, according to the present invention, the contact state of the sliding portion is unstable, the return torque is large (the operability is poor), the return torque in the initial stage of assembly is reduced, and then the return is made when the contact state when the tensioner is used is stabilized. It has the characteristic that the torque increases from the initial stage and the operation resistance against high input increases.

Further, in the present invention, it is possible to change the characteristics of the return torque value by changing the film strength of the solid lubricant. The part to which the solid lubricant is applied is not limited to each part shown in FIG. 1, and is not particularly limited, for example, a case, a spring, a cap, a spacer, and the like. in any case,
It can be applied and formed on each sliding part.

[0024]

As described above, according to the first and second aspects of the present invention, the return torque value is minimum at the beginning of use of the device, and thereafter, the return torque value is quickly stabilized. No tensioning is required immediately after the start of use, and it is possible to estimate the amount of endurance degradation to a small extent.Therefore, a tensioner with a wide range of specifications and a high degree of freedom in equipment design is realized. it can.

Similarly, in the inventions according to the third and fourth aspects, it is not necessary to apply immediately after the start of use.
The durability degradation can be underestimated and therefore
The specification setting range is expanded, and a method for stabilizing the operation of the tensioner with a high degree of freedom in equipment design can be realized.

[Brief description of the drawings]

FIG. 1 is an exploded view for explaining a main sliding portion of a screw type tensioner 1. FIG.

FIG. 2 is a graph conceptually showing the transition of the return torque value from the initial use to the end of endurance for the screw type tensioner 1 and the conventional product.

FIG. 3 is a diagram illustrating an example of a mounting layout of a tensioner attached to an engine body.

FIG. 4 is a longitudinal sectional view showing details of the tensioner 1 as an example shown in FIG. 3;

FIG. 5 is a conceptual graph showing a method for measuring a characteristic of a return torque value of the tensioner 1, and a diagram showing heavy and smooth operation.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Tensioner 2 Case 3 1st shaft member 3a Male screw part 4 2nd shaft member 4a Female screw part 7 Shaft receiving member 8 Torsion spring 9 Bearing

Claims (4)

[Claims] A first shaft member and a second shaft member screwed together by a screw portion; a spring for urging the first shaft member to rotate in one direction; and a first shaft member and a second shaft member. A case that has a sliding portion that slidably supports the shaft member of the first shaft member and the case that accommodates the first shaft member and the second shaft member, and restrains rotation of the second shaft member. In a tensioner for converting a rotational urging force of a spring into a unidirectional propulsion force of a second shaft member, a solid lubricant film is formed on the screw portion and other sliding portions including the sliding portion. And tensioner. 2. The tensioner according to claim 1, wherein the solid lubricant is made of one of molybdenum, fluororesin, graphite, and phosphate, or a mixture thereof. 3. A first shaft member and a second shaft member screwed by a screw portion, a spring for urging the first shaft member to rotate in one direction, and a first shaft member and a second shaft member. A case that has a sliding portion that slidably supports the shaft member of the first shaft member and the case that accommodates the first shaft member and the second shaft member, and restrains rotation of the second shaft member. A method for stabilizing the operation of a tensioner that converts a rotational biasing force of a spring into a unidirectional propulsion force of a second shaft member, wherein a solid lubricant film is formed on the screw portion and other sliding portions including the sliding portion. A method for stabilizing the operation of a tensioner, characterized in that a tension is formed. 4. The operation stabilization of a tensioner according to claim 3, wherein the solid lubricant is made of any one of molybdenum, fluororesin, graphite, and phosphate, or a mixture thereof. Method.