RU47065U1 - HYDRA-TENSIONER FOR BELT TENSIONING DEVICE - Google Patents

Abstract

The inventive utility model relates to the field of mechanical engineering (mainly to motor engineering) and is intended for use in the construction of belt tensioners. The purpose of the claimed utility model is to improve the well-known hydraulic belt tensioners by simplifying the design, improving manufacturability and reducing the complexity. This goal is achieved in that the hydraulic tensioner comprises a hollow cylindrical body with an eye, a step sleeve located inside the body with an integrated non-return valve, an earring with a plunger forming a precision pair with the sleeve, a power spring, a telescopic rubber sleeve connecting and sealing the case to the earring on the outer surfaces of the case characterized in that the step sleeve along the cylindrical surface of a larger diameter is installed in the mating cylindrical surface of the housing along the movable landing e, and between the upper end of the valve seat and the inner end of the stepped sleeve, an o-ring is installed.

Description

The inventive utility model relates to the field of mechanical engineering (mainly to the motor industry) and is intended for use in the construction of belt tensioners (chains).

Known hydraulic tensioners for devices for tensioning belts (chains) "INA" Germany, catalog number "STA" No. 161142, comprising a hollow cylindrical body with an eye, a sleeve located inside the body with an integrated non-return valve, an earring with a plunger that forms a precision pair with the sleeve, power a spring, a telescopic rubber cuff connecting the case to the earring on the outer surfaces. The internal cavity of the hydraulic tensioner is filled with engine oil.

The disadvantages of the design of this hydraulic tensioner are:

1. Unstable operation of the hydraulic tensioner when moving the plunger relative to the sleeve in the direction of increasing the center distance between the axes of the housing and the earring. At the same time, a vacuum may occur in the cavity under the plunger and, as a result, the saddle will tear off together with the sleeve from the hydraulic tensioner housing, which may cause increased knocking (noise) and premature failure of the hydraulic tensioner.

2. In this design, air bleeding from the cavity under the plunger is slowed down, since it is possible only through the gap between the sleeve and the plunger, which can also be the cause of increased noise and unstable operation of the hydraulic tensioner during starting conditions.

3. Due to the fact that the casing and the earring are not rigidly connected and are interconnected only by a power spring and the cuff, when the tensioner is working, the axes of the housing and the earring may be skewed, which can cause premature wear of the cuff and failure of the tensioner.

Deprived of the listed disadvantages and the closest analogue in design to the claimed utility model is a hydraulic tensioner for a belt (chain) tensioning device according to RF patent No. 2233395, which contains: a hollow cylindrical body with a spring, a sleeve with a built-in non-return valve located inside the body, an earring with a plunger, forming with a sleeve

a precision pair, a power spring, a telescopic rubber sleeve connecting and sealing the housing with an earring on the outer surfaces, characterized in that the connection of the hydraulic tensioner housing with the sleeve is threaded,) the sleeve is made in the form of a two-stage cylinder, on the larger outer diameter of which there is a thread. At the end of the sleeve, on the larger diameter side, there is a concentric bore under the non-return valve seat, at the end of which there is a groove for supplying oil to the axial bore of the non-return valve seat, the axial size of the bore being smaller than the axial size of the non-return valve seat, and the cavity under the end of the sleeve and the cavity of the power spring are connected channels. A beveled longitudinal groove (or flat) is made on the precision surface of the plunger from the side of its free end on approximately one third of the length of the plunger. The seat of the non-return valve is installed in the bore of the sleeve in a movable fit and sealed by an o-ring.

A significant drawback of this hydraulic tensioner is the design complexity, which consists in the presence of a threaded connection between the two-stage sleeve and the housing. This threaded connection degrades manufacturability and increases the complexity of the product as a whole.

The purpose of the claimed utility model is to improve the well-known hydraulic belt tensioners (chains) by simplifying the design, improving manufacturability and reducing the complexity.

This goal is achieved in that the hydraulic tensioner comprises a hollow cylindrical body with an eye, a step sleeve located inside the body with an integrated non-return valve, an earring with a plunger forming a precision pair with the sleeve, a power spring, a telescopic rubber sleeve connecting and sealing the case to the earring on the outer surfaces of the case , characterized in that the stepped sleeve on a cylindrical surface of a larger diameter is installed in the mating cylindrical surface of the housing on a movable landing, and between the upper end of the valve seat and the inner end of the stepped sleeve, an o-ring is installed.

The hydraulic tensioner according to claim 1, characterized in that the o-ring is made with a cross section of a rectangular profile, and the inner diameter of the o-ring d _{2 is} made smaller than the inner diameter of the axial bore of the sleeve d ₁ in contact with the o-ring in the ratio d ₁ > d ₂ .

The hydraulic tensioner according to claim 1, characterized in that a longitudinal groove is made on the outer cylindrical surface of the larger diameter of the sleeve, connecting the cavity of the power spring with the oil supply channel under the check valve ball.

The essence of the proposed technical solution is illustrated by drawings, where:

Figure 1 - shows a longitudinal section of the hydraulic tensioner in two extreme positions: the section to the left of the longitudinal axis shows the position of all parts of the hydraulic tensioner in the expanded state of the hydraulic tensioner; to the right of the longitudinal axis is the position of the hydraulic tensioner parts in a compressed state.

Figure 2 - shows on an enlarged scale the relative position of the stepped sleeve, o-ring and valve seat.

The hydraulic tensioner for the belt (chain) tensioning device includes a housing 1, a stepped sleeve of a plunger 2 with an integrated valve seat 3, an earring 4 with a plunger 5 pressed into it. Plunger 5 with a sleeve 2 make up a precision pair. The hydraulic tensioner also includes a cuff 6, a power spring 7, a locking ring 8. The sleeve 2 is installed in the housing 1 along a cylindrical surface 9. A sleeve 11 and a valve seat 3 with an end groove 12 and an axial channel 13 are installed in the sleeve 2 with a groove 10 for oil supply In the upper bore 14 of the seat 3, the check valve parts are installed: cap 15, spring 16 and ball 17 (figure 2). On the cap 15 there are grooves 18 for supplying oil to the cavity 19. The bushings 20 and 21 are mounted in the eyes of the housing 1 and the earrings 4, in the holes 22 and 23 of which the fingers (not shown) of the kinematic mechanism of the tensioner are mounted. On the precision surface 24 of the plunger, a longitudinal beveled groove 25 and an annular groove 26 for the locking ring 8. An inner cylindrical bore of the upper part of the sleeve 2 includes a precision surface 27 and a surface 28 of a slightly larger diameter in the lower part of the stepped sleeve 2. On the inner bore at the top of the stepped of the sleeve 2 there is an entry chamfer 30. The seal between the surface 31 of the stepped sleeve 2 and the surface 32 of the valve seat 3 is made by means of a rubber ring 11, the cross section of which has a rectangular shape, and the inner diameter d _{2 is} slightly smaller than the inner diameter d ₁ of the sleeve step 2 (Figure 2).

Assembly sequence for hydraulic tensioner:

A sealing ring 11 is installed in the cylindrical bore 33 of the sleeve 2 and a valve seat 3 with movable fittings with a check valve parts: a cap 15, a spring 16 and a ball 17. Then a power spring 7 is installed, and the working oil is poured into the cavity 34 to approximately the level of section 1 -1 (figure 1). The earring 4 with the plunger 5 pressed into it with the locking ring 8 located in the groove 26 and the bushings 20 and 21 installed in the earring is inserted with the necessary force by the free end of the plunger through the entry chamfer 30 into the hole 27 on the sleeve 2. In this case, the locking ring 8 is compressed to the diameter of the surface 27. At this moment, the air column located in the sleeve 2 and determined by the distance between the end face of the plunger 5 and the oil level in the cavity 19 of the sleeve 2 is easily displaced through the groove 25 of the plunger 5, since the spring cavity 34 is connected through the groove 25 with internal the early cavity 19. With further movement of the plunger 5 in the sleeve 2, only oil is displaced at first through the groove 25 and the precision gap between surfaces 24 and 27, and then only through the precision gap. When the locking ring 8 enters the cavity 19, the ring 8 is expanded and the plunger is fixed relative to the sleeve. Next, put on a rubber cuff 6.

All hydraulic tensioner assembly operations are performed in the vertical position of the hydraulic tensioner with earring 4 up.

After installing the cuff 6, the tensioner is installed on the engine. When installed on the engine, the distance between the axes of the holes 22 and 23 is chosen so as to provide the necessary working stroke of the hydraulic tensioner, providing the required belt (chain) tension during the specified engine life.

When working on the engine, the necessary belt tension is ensured by the force of the power spring 7, and as the belt (chain) is worn out and the plunger 5 is pulled out of the sleeve 2 under the action of the spring 7, the distance between the axes of the holes 22 and 23 increases, providing constant contact between the tensioner and the belt (chain).

When the plunger 5 is pulled out of the sleeve 2 in the cavity 19, a vacuum is formed, due to which the check valve ball 17, overcoming the tightening of the spring 16, opens, and the quantity necessary for filling the cavity 19 enters the cavity 19 through the grooves 10, 12 and the channel 13 oils.

When moving the plunger in the opposite direction towards compression

spring 7 under the action of increasing pressure in the cavity 19, the ball of the check valve hermetically closes the channel 13, the cavity 19 becomes almost closed. Due to the displacement of oil from the cavity 19 through the precision gap between the surfaces 24 and 27, the necessary damping of the entire mechanism of the tension of the belt (chain) occurs.

If between the annular surfaces 31 and 32 there is no reliable seal over the entire area of the indicated surfaces, then the pressure in the cavity 19 will act on the annular surfaces 31 and 32, as a result of which the vertical force on the surface 31 can exceed the force of the spring 7 and the sleeve 2 will tear off saddles 3. In order to prevent this separation, a flat sealing ring with a cross-section of a rectangular profile is installed between surfaces 31 and 32. The preload of the spring 7 provides the necessary deformation of the sealing ring 11, and the execution of the ring 11 with a cross-section of a rectangular profile and with an inner diameter d ₂ slightly smaller than the inner diameter d _{1 of the} stepped sleeve 2 ensures reliable sealing between the surfaces 31 and 32. This ensures the integrity of the design of the stepped sleeve 2 with the seat 3. Installing the stepped sleeve 2 in the housing 1 on a movable landing provides a simple technology for assembling and disassembling the hydraulic tensioner.

The preliminary deformation of the spring 7 in the unclenched position of the hydraulic tensioner (Fig. 1, the position to the left of the longitudinal axis) is also selected from the condition of ensuring reliable preloading of the stepped sleeve 2 with the seat 3 to the inner end 35 of the housing 1.

Thus, the implementation of the hydraulic tensioner in the form of a hollow cylindrical body with a stepped sleeve located inside the body, containing a check valve and a plunger, forming a precision pair with the stepped sleeve and pressed into the earring connected to the body by means of a telescopic rubber sleeve, characterized in that the stepped sleeve is cylindrical surface of larger diameter is installed in the mating cylindrical surface of the housing by movable landing, and the seal between the sleeve and the seat Pan formed by a rubber ring with a rectangular profile cross-section located between the upper end of the valve seat and the inner end of the stepped sleeve, and having on the outer cylindrical surface of the larger diameter step of the sleeve longitudinal

the groove connecting the cavity of the power spring with the channel for supplying oil under the check valve ball, significantly simplifies the design of the hydraulic tensioner, improves manufacturability and reduces the complexity of manufacturing while maintaining reliable performance of the product.

Claims (3)

1. The tensioner of the device for belt tension, comprising a hollow cylindrical body with an eye, a step sleeve located inside the case with an integrated check valve, an earring with a plunger forming a precision pair with the step sleeve, a power spring, a telescopic rubber sleeve connecting and sealing along the outer surfaces of the case with an earring, characterized in that the step sleeve along the cylindrical surface of a larger diameter is installed in the mating cylindrical surface of the housing by moving seated, and between the upper end of the valve seat and the inner end of the stepped sleeve, an o-ring is installed. 2. The hydraulic tensioner according to claim 1, characterized in that the o-ring is made with a cross-section of a rectangular profile, and the inner diameter of the o-ring d _{2 is} made smaller than the inner diameter of the axial bore of the sleeve d ₁ in contact with the o-ring in the ratio d ₁ > d ₂ . 3. The hydraulic tensioner according to claim 1, characterized in that a longitudinal groove is made on the outer cylindrical surface of the larger diameter of the sleeve, connecting the cavity of the power spring with an oil supply channel under the check valve ball.