RU212859U1 - AIR SPRING OF VEHICLE SUSPENSION - Google Patents

Abstract

The utility model relates to vehicle suspensions, in particular to air springs with integrated air dampers. The technical result of the claimed utility model is to increase the reliability and durability of the vehicle air spring. The specified technical result is achieved by the fact that at the lower ends of the first and second cylindrical sleeves a protective cover is fixed, made in the form of a truncated corrugated cone and forming an annular conical cavity with the second cylindrical sleeve and a guide box, communicated with the auxiliary working container through an additional calibrated hole and an additional return valve and communicated with the external environment by means of a connecting tube installed vertically outside the first cylindrical cup, at the upper end of which a filter is installed.

Description

The utility model relates to vehicle suspensions, in particular to air springs with integrated air dampers.

Known air spring (a. with. RF No. 87663, B60G 11/26, 2008 publ. - with a hollow body made with holes for connecting the cavities of the flexible shell and the hollow body, equipped with a support for fastening to the unsprung part of the vehicle, a shock absorber fixed on the hollow body inside the flexible shell, and an internal support.

Known air suspension spring of a vehicle (utility model patent RF 134263, class F16F 9/04, publ. 2013), containing a cylinder with a flange to which the cover is attached, a support made in the form of a steel hemisphere with a hollow rod included into a cylinder with a small gap, and a flexible shell, the upper part of which is connected to the cylinder cover by means of a flange, the lower part is located on a support, the cover being attached to the sprung part of the vehicle, and the lower part of the hollow rod to the unsprung part of the vehicle.

The disadvantages of these springs is the lack of built-in air damping devices designed to dampen suspension vibrations, which leads to a deterioration in ride smoothness and a limitation in vehicle speeds, especially on broken roads.

The closest of the known technical solutions is a vehicle suspension air spring (utility model patent RF 192934, class F16F 9/04, publ. 2019, containing the main elastic element, consisting of the first cylindrical cup with an axial hole at its lower end, a rubber-cord shell placed inside the first cylindrical cup, working and additional tanks and a partition located between them with a main calibrated hole and a main check valve that closes during recoil, and an auxiliary elastic element consisting of a second cylindrical cup installed in the axial hole of the lower end of the first a cylindrical cup, an auxiliary working container, an additional calibrated hole and an additional check valve, while the partition is connected to the upper end of the second cylindrical cup and forms a working space with the rubber-cord shell and the upper end of the first cylindrical cup bone, which communicates with an additional container placed inside the second cylindrical cup, through the main calibrated hole and the main check valve, which is closed during the recoil, and the axial hole of the lower end of the first cylindrical cup is made in the form of a guide box, providing axial movement of the second cylindrical cup and forming with a rubber-cord sheath, the first and second cylindrical cups, an auxiliary working container communicated with the external environment through an additional calibrated hole installed in the guide box and an additional check valve that is closed during recoil.

The disadvantage of this vehicle suspension air spring is its relatively low reliability, since an additional calibrated hole and an additional check valve installed at the lower end of the first cylindrical cup and forming an additional damping system can quickly fail if dust, dirt, or water splashes enter them. or snow from under the wheels of the car, which will lead to a partial loss of the damping properties of the air suspension and a decrease in ride smoothness. In addition, the second cylindrical cup, unprotected from stones, dust and dirt, installed in the guide box, can be easily damaged, which will lead to loss of tightness of the guide box and reduce the efficiency of the additional damping system, resulting in a decrease in the smoothness of the car.

In this regard, the most important task is to create such an air spring for the suspension of a vehicle, in which the second cylindrical cup and the additional damping system would be protected from clogging with dust, dirt, moisture and direct ingress of stones from under the wheels of the car by using a protective cover for the second cylindrical glass and filter for an additional damping system, installed more remote from the wheels.

The technical result of the claimed utility model is to increase the reliability and durability of the vehicle suspension air spring.

The specified technical result is achieved by the fact that in the air spring of the suspension of the vehicle, containing the first cylindrical cup, inside which the second cylindrical cup is installed, closed from above by a partition, a rubber-cord shell placed inside the first cylindrical cup and forming a working capacity with the partition and the upper part of the first cylindrical cup , communicated with an additional container placed inside the second cylindrical cup through the main calibrated hole and the main check valve installed in the partition, which is blocked during the recoil, the guide box installed in the lower part of the first cylindrical cup and forming with the rubber-cord shell, the first and second cylindrical cups an auxiliary working container, an additional calibrated hole and an additional check valve are installed in the guide box, which is blocked during the return stroke, and at the lower ends of the first and second cylinders In the indric sleeves, a protective cover is fixed, made in the form of a truncated corrugated cone and forming an annular conical cavity with the second cylindrical sleeve and a guide axle box, communicated with the auxiliary working container through an additional calibrated hole and an additional check valve and communicated with the external environment by means of the first cylindrical cup of the connecting tube, at the upper end of which a filter is installed.

This utility model is characterized in that in the air spring of the vehicle suspension, at the lower ends of the first and second cylindrical cups, a protective cover is fixed, made in the form of a truncated corrugated rubber cone and forming an annular conical cavity with the second cylindrical cup and the guide axle box, communicated with the auxiliary working capacity through an additional calibrated hole and an additional check valve, which is blocked during the return stroke, and communicated with the external environment by means of a connecting tube installed vertically outside the first cylindrical cup, at the upper end of which a filter is installed.

As a result, the outer surface of the second cylindrical cup and the additional damping system are protected from damage due to possible ingress of stones from under the wheels and clogging with dust, dirt and moisture, which ultimately increases the reliability and durability of the air spring of the vehicle suspension.

The drawing shows a General view of the air spring suspension of the vehicle.

The air spring of the vehicle suspension contains the first cylindrical cup 1, inside which the second cylindrical cup 3 is installed in the guide box 2, closed from above by a partition 4. Inside the first cylindrical cup 1, a rubber-cord sheath 5 is installed, forming with the partition 4 and the upper part of the first cylindrical cup 1 a working container 6. The working container 6 communicates with the additional container 7, placed inside the second cylindrical cup 3, through the main calibrated hole 8 and the main check valve 9 installed in the partition 4, which are closed during the recoil. The guide box 2 forms an auxiliary working container 10 with a rubber-cord shell 5, the first 1 and the second 3 cylindrical cups. An additional calibrated hole 11 and an additional check valve 12 are installed in the guide box 2, made in the form of a flat rubber ring and overlapped during recoil.

At the lower ends of the first 1 and second 3 cylindrical cups, a protective cover 13 is fixed, made in the form of a truncated corrugated cone and forming an annular conical cavity 14 with the second cylindrical cup 3 and a guide box 2. The annular conical cavity 14 communicates with the auxiliary working tank 10 through an additional calibrated hole 11 and an additional check valve 12, which is closed during the return stroke, and is also communicated with the external environment by means of a connecting tube 15 installed vertically outside the first cylindrical cup 1, at the upper end of which a filter 16 with a desiccant filler is installed. In winter, the outer channel of the filter 16 can be connected to the passenger compartment, which will reduce the fuel consumption for heating it.

An elastic shock absorber 17 is installed on the upper end of the partition 4, which limits the maximum compression stroke of the air spring, which is attached to the vehicle suspension using the upper 18 and lower lugs 19, mounted along the axis of the spring on cylindrical cups 1 and 3. Working capacity 6 and additional capacity 7 are filled with air to the required static pressure through the fitting 20 installed on the top of the first cylindrical cup 1.

The rubber-cord shell 5, the working tank 6, the additional tank 7 and the partition 4 located between them with the main calibrated hole 8 and the main check valve 9 form the main elastic element of the spring, which provides the perception of the axial load and damping of the suspension vibrations due to the internal throttling of air between the working 6 and additional 7 containers.

The auxiliary elastic element of the spring consists of a rubber-cord shell 4, an auxiliary working tank 10, an additional calibrated hole 11 and an additional check valve 12. It provides suspension vibration damping due to external air throttling between the auxiliary working tank 10 and the external environment.

The proposed air spring suspension of the vehicle works as follows.

During the compression of the spring, filled with air through the fitting 20, the first 1 and second 3 cylindrical cups attached with the help of the upper 18 and lower lugs 19 to the sprung and unsprung parts of the vehicle telescopically move towards each other in the hole of the guide box 2. In this case, the lower part of the rubber-cord shell 5 in the bend zone moves upward, rolling up along the inner surface of the first cylindrical sleeve 1 and down along the outer surface of the second cylindrical sleeve 3, and the protective cover 13 is compressed. As a result, the pressure in the working tank 6 increases, and the air from it flows freely into the additional tank 7 through the main calibrated hole 8 and the check valve 9 installed in the partition 4. At the same time, the pressure in the auxiliary working tank 10 gradually decreases and becomes lower than the ambient pressure. environment. Under the action of a pressure difference, air from the environment is freely sucked into the auxiliary working tank 10 through the filter 16, the connecting tube 15, the annular conical cavity 14, the additional calibrated hole 11 and the additional check valve 12. At the end of the compression stroke, the elastic shock absorber 17, mounted on the partition 4 , interacts with the upper end of the first cylindrical cup 1, which elastically limits the maximum compression stroke, protecting the suspension from hard impact in the event of its breakdown.

During the spring recoil, the first 1 and second 3 cylindrical cups telescopically move in opposite directions relative to each other. In this case, the lower part of the rubber-cord shell 5 in the bend zone moves down, rolling down along the inner surface of the first cylindrical sleeve 1 and up along the outer surface of the second cylindrical sleeve 3, and the protective cover 13 is stretched. As a result, the pressure in the working tank 6 decreases, and the air from the additional tank 7 flows into the working tank 6 through the main calibrated hole 8, since the main check valve 9 is closed. When throttling through the main calibrated hole 8, the air heats up and gives off its heat to the walls of the first 1 and second 3 cylindrical cups, which is dissipated into the environment. In this case, the pressure in the auxiliary working tank 10 increases, the additional check valve 12 closes and the air from the auxiliary working tank 10 is squeezed out into the environment through an additional calibrated hole 11, an annular cavity 14, a connecting tube 15 and a filter 16. As a result, heated during throttling through an additional calibrated hole 11, the air is discharged during the recoil into the environment, practically without heating the spring.

At the end of the return stroke and the beginning of the subsequent compression stroke, the pressures in the working tank 6 and the additional tank 7 gradually equalize, and the pressure in the additional working tank 10 becomes equal to the pressure in the environment. During the subsequent compression stroke, the process of air flow inside the spring is repeated.

As a result of the joint work of the protective cover 13, the connecting tube 15 and the filter 16, the second cylindrical cup 3 and the additional damping system are protected from clogging with dust, dirt, moisture and direct hit of stones from under the wheels of the car.

Thus, the claimed technical result of the proposed utility model is achieved, which consists in increasing the reliability and durability of the air spring of the vehicle suspension.

Claims (1)

Pneumatic spring suspension of a vehicle, containing the first cylindrical cup, inside which is installed the second cylindrical cup, closed from above by a partition, rubber-cord shell placed inside the first cylindrical cup and forming a working container with the partition and the upper part of the first cylindrical cup, communicated with the second cylindrical cup located inside the second cylindrical cup additional container through the main calibrated hole installed in the partition and the main check valve, which is blocked during the return, the guide box installed in the lower part of the first cylindrical sleeve and forming an auxiliary working container with the rubber-cord shell, the first and second cylindrical sleeves, an additional calibrated an opening and an additional check valve, which is closed during the recoil, characterized in that a protective valve is fixed at the lower ends of the first and second cylindrical a cover made in the form of a truncated corrugated cone and forming an annular conical cavity with the second cylindrical sleeve and the guide box, communicated with the auxiliary working tank through an additional calibrated hole and an additional check valve and communicated with the external environment by means of a connecting tube installed vertically outside the first cylindrical sleeve, at the top end of which a filter is installed.

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