RU2571145C1 - Absorbing device - Google Patents

Abstract

FIELD: transportation.

SUBSTANCE: absorbing device contains the cylinder implemented with two interconnected cavities filled with viscoplastic liquid. One of cavities has the bedplate, the stem with piston implemented with a possibility of providing of overflowing of working liquid. On the bedplate bottom coaxially with the stem, at least one elastic element is installed. The piston is implemented in the form of two cylindrical surfaces with the central channel separated by the groove. The first surface is implemented with the cavity and the bearing and the guiding ring installed in the cavity. The second surface is implemented with a possibility of formation of calibrated gap between the piston and the cylinder cavity.

EFFECT: increase of energy intensity of the device, improvement of dissipative properties and improvement of reliability.

4 cl, 1 dwg

Description

The invention relates to railway transport, in particular to coupler devices providing the connection of wagons and head cars (locomotives) of railway vehicles, and is intended to provide effective protection of the design of the car and the cargo carried in it from the action of longitudinal loads arising from shunting on sorting slides and in transient modes of running the train.

The prior art hydrogas absorbing apparatus of an automatic coupler (see aut. USSR certificate No. 525581, IPC B21G 11/12, publ. 11/17/1976), which contains a cylinder with a lid, divided into two parts by a partition with the formation of gas and hydraulic chambers. A piston with a rod is placed on one side of the baffle, and a floating piston on the other. The design of the apparatus used seals. The disadvantage of the apparatus according to the specified technical solution is its significant metal consumption, as well as the complexity of the seals used to maintain the design under high pressure.

Also known is a friction-polymer absorbing coupler device (see RF patent No. 2397896, IPC B61G 11/00, published August 27, 2010), comprising a housing inside which movable and stationary friction plates and a spacer block, preloaded with polymer elastic elements, are filled volumetric compressible elastomer, and movable and fixed friction plates are made with slopes.

A disadvantage of the known absorbing device of the automatic coupler is the inability to ensure the safety of the spacer unit, since the longitudinal force from the automatic coupler through the thrust plate is directly transmitted to the spacer unit. In addition, the disadvantages include the fact that the space between the friction plates, in which the spacer block is placed, is limited and it is extremely difficult to place the spacer block of the required dimensions to ensure strength conditions. There is a reduced design reliability due to the possibility of jamming during restoration during its operation in an automatic coupler.

The closest in technical essence is an absorbing apparatus (see RF patent No. 2446068, IPC B61G 11/12, publ. 03/27/2012) containing a cylinder made with two interconnected cavities filled with a viscoplastic fluid, one of which has a bottom the cylinder, the piston rod, made with the possibility of overflowing of the working fluid, while in one of the cavities of the cylinder are installed coaxially with the housing, elastic elements made of elastoplastic material and separated by separators located coaxially with the body and having grooves around the perimeter, holes and central channels to ensure the flow of viscoplastic fluid between the cavities.

The design of the known absorbing apparatus allows to reduce the pressure of a viscoplastic fluid in the apparatus by 25 ... 30%.

To improve operational characteristics, it is proposed to install at least one additional elastic element made of an elastoplastic material and mounted on the bottom of the cylinder coaxially with the rod, as well as the presence of a central chamber in the rod, and in the piston and separators of additional channels to ensure more stable viscoplastic flow fluid between the cavities, which will increase the energy intensity of the apparatus, improve its dissipative characteristics and increase reliability in operation.

The problem to which the claimed technical solution is directed is to create an absorbing apparatus of increased energy intensity, improved dissipative properties, as well as higher reliability in operation.

The technical result achieved by the implementation of the present invention is to increase the energy intensity of the apparatus, improve dissipative properties, increase reliability.

The problem underlying the present invention is solved by the fact that in an absorbing apparatus comprising a cylinder made with two interconnected cavities filled with a viscoplastic liquid, in one of which a bottom is installed, a rod with a piston made with the possibility of flowing of the working fluid, at the same time, elastic elements made of an elastoplastic material and separated by coaxially located separators having grooves along atimeters with support rings installed in them, holes and central channels for ensuring the flow of a viscoplastic fluid between the cavities, at least one elastic element is installed coaxially with the rod on the bottom, the piston is made in the form of two cylindrical surfaces with a central channel separated by a groove moreover, the first surface is made with a groove and a support-guide ring installed in the last, and the second with the possibility of the formation of a calibrated gap between the piston and the cylinder cavity but.

In addition, the piston is made with a central channel connected by inclined channels with a piston hydraulic cavity, the first cylindrical surface of the piston is stepped with peripheral channels, and transverse channels connecting the central channel with the piston hydraulic cavity are located in the bottom part of the groove.

In addition, the separators are made of the Central, peripheral and transverse channels connecting the Central channel with a piston hydraulic cavity.

In addition, the second cylindrical surface of the piston is provided with peripheral channels with reverse valves located therein.

Installing at the bottom of the cylinder coaxially with the rod, at least one elastic element in combination with elastic elements located in the piston hydraulic cavity, as well as the implementation of the piston with a Central cavity in the form of two cylindrical surfaces separated by a groove, one of which is made with a groove and installed in the last supporting guide ring of the piston, and the other with the possibility of the formation of a calibrated gap between the piston and the inner wall of the cylinder, can reduce the pressure in the cylinder absorbs apparatus, the external apparatus of the perceived load on the stem is defined as the sum of the three loads:

- F _{EL 9} - load perceived by elastic elements located inside the cylinder;

- F _{EL 15} - load perceived by elastic elements located outside the apparatus on the rod;

- F _DAVL - the load on the rod of the apparatus created by the pressure of a viscoplastic fluid.

It follows that, with the perception of the same maximum load, the absorbing apparatus of the proposed design, the maximum pressure of a visco-plastic fluid in the apparatus is lower than that of the prototype.

These signs are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the specified technical result.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the invention does not explicitly follow for a specialist in the field of couplers of freight cars, showed that it is unknown, and taking into account the possibility of industrial serial production of an absorbing apparatus, we can conclude that it meets the criteria patentability.

The prior art also does not confirm the popularity of the influence of the distinctive features of the claimed invention on the technical result indicated by the applicant, therefore, the claimed invention meets the condition of "inventive step".

A preferred embodiment of the absorbing apparatus is illustrated in the drawing, which shows a General view in section of the proposed absorbing apparatus.

In the drawing, the corresponding structural elements of the absorbing apparatus are indicated by the following positions:

1 - stock;

2 - support-guide ring of the rod;

3 - bottom;

4 - stem-bottom seal;

5 - the central channel of the rod;

6 - bottom-body seal;

7 - piston hydraulic cavity;

8 - inclined piston channel;

9 - peripheral channel with a reverse valve;

10 - calibrated clearance;

11 - a piston;

12 - piston groove with a transverse channel;

13 - supporting guide ring of the piston;

14 - peripheral channel for flow in the piston;

15 - internal elastic element;

16 - piston hydraulic cavity;

17 - supporting guide ring of the separator;

18 - peripheral channel for flow in the separator;

19 is a transverse channel in the separator;

20 - thrust plate;

21 - a coupling bolt;

22 - external elastic element;

23 - spacer sleeve;

24 - mounting unit of the coupling bolt;

25 - case (cylinder);

26 - a hydraulic cavity of elastoplastic elements;

27 - the Central channel for overflow in the separator;

28 - separator;

29 - base plate;

30 - intermediate plate.

The absorbing apparatus comprises a cylindrical housing 25, a support plate 29 and a thrust plate 20 connected to the housing by means of a fastener 24 of the coupling bolts 21. The housing (cylinder) 25 is made with two interconnected hydraulic cavities 7 and 16 filled with a viscoplastic fluid, in one of which (7) a bottom 3 is installed, a rod 1 with a piston 11 configured to allow the flow of the working fluid, while in the other cavity 16 of the cylinder 25, elastic elements 15 made of an elastoplastic material are coaxial with it rial and separated by separators 28, located coaxially with the cylinder 25 and having grooves around the perimeter for installing the support-guide rings of the separator, holes and central channels to ensure the flow of visco-plastic fluid between the cavities. At the bottom 3, coaxially with the rod 1, at least one elastic element 22 is installed, the piston 11 is made in the form of two cylindrical surfaces with a central channel 5 separated by a groove, the first surface being made with a groove and a support ring 13 installed in the last, and the second - with the possibility of the formation of a calibrated gap 10 between the piston 11 and the inner wall of the cylinder 25. The piston 11 is made with a Central channel 5 connected by inclined channels 8 with a piston hydraulic cavity 7, while the first cylinder The piston’s surface is stepped with peripheral channels 14, and in the bottom part of the groove there are transverse channels 12 connecting the central channel 5 with the piston hydraulic cavity 16. In the separators 28 there are central 27, peripheral 18 and transverse 19 channels connecting the central cavity 26 of the elastoplastic elements 15 with a piston 16 hydraulic cavity. The second surface of the piston 11 is provided with peripheral channels 9 with reverse valves located therein.

The absorbing apparatus during quasistatic compression works as follows.

Under the action of a compressive load, the rod 1 with the piston 11 is moved inside the hydraulic cavity 16, due to which there is a compression of the internal elastic elements 15, a decrease in the volume of the hydraulic cavities 16, 26 and increase in pressure. This creates a force that prevents the compression of the absorbing apparatus, consisting of the compression force of the internal elastic elements and the pressure on the rod with the piston of a viscoplastic fluid.

When the compression of the rod reaches approximately 60 ... 70% of the total compression, the outer elastoplastic element 22 is compressed coaxially with the rod 1 on the bottom 3, due to which an additional force arises preventing the compression of the apparatus.

During dynamic compression of the apparatus, a viscoplastic fluid from the piston hydraulic cavity 16 flows through the calibrated gap 10 between the piston and the cylinder into the piston hydraulic cavity 7, a pressure differential is created between the piston hydraulic cavity and the piston hydraulic cavity, which creates an additional force that prevents compression of the absorbing apparatus.

With a direct stroke of the rod 1 with the piston 11 of the valve 9, located around the circumference of the piston, they are closed and prevent the viscoplastic fluid from flowing from the hydraulic cavities 16 and 26 into the hydraulic piston cavity 7.

Also, during dynamic compression of the apparatus, the viscoplastic fluid located in the hydraulic cavity 26 of the internal elastic elements 15 is displaced through the central channels 27, transverse channels 19 and peripheral channels 18 into the piston hydraulic cavity 16, and through the central channel 5 of the rod, transverse channels 12 and inclined channels 8 in the piston into the piston hydraulic cavity 7.

The dissipation of the absorbed energy occurs mainly due to the transfer of heat energy from the hydraulic resistance to flow into the calibration gap of a viscoplastic fluid filling the hydraulic cavities.

The return of the rod with the piston during the reverse stroke occurs due to the efforts of the compressed internal elastic elements 15 and the pressure in the hydraulic cavities 16 and 26. During the reverse stroke of the rod with the piston of the reverse valve 9 open, providing minimal resistance to the output of the rod with the piston.

In terms of installation dimensions, the proposed absorbing apparatus is completely interchangeable with absorbing devices of the spring-friction type and is installed in the traction clamp of the automatic coupler using the technology for installing these apparatuses.

The proposed technical solution allows to reduce the pressure of a viscoplastic fluid in an absorbing apparatus by 50 ... 55%.

A sample of the proposed absorbing apparatus was developed on the basis of detailed experimental studies of the design parameters of the apparatus and the process of its operation, and is intended for installation on gas tanks, as well as freight cars carrying especially dangerous goods (explosives, explosives, etc.).

The design of the absorbing apparatus is simple to manufacture, does not require the development of new equipment and the re-equipment of existing facilities, and the tools used are widely used in railway transport, which confirms the possibility of practical implementation and achievement of the technical result.

Claims (4)

1. An absorbing apparatus comprising a cylinder made with two interconnected cavities filled with a viscoplastic liquid, in one of which a bottom is installed, a rod with a piston made with the possibility of overflowing of the working fluid, while one of the cylinder cavities is mounted coaxially with the last elastic elements made of an elastoplastic material and separated by coaxially arranged separators having perimeter grooves with support rings installed in them, holes ia and central channels to ensure the flow of a viscoplastic fluid between the cavities, characterized in that at least one elastic element is installed coaxially with the stem on the bottom, the piston is made in the form of two cylindrical surfaces with a central channel separated by a groove, the first surface being made with a groove and installed in the last support-guide ring, and the second - with the possibility of the formation of a calibrated gap between the piston and the cylinder cavity. 2. The apparatus according to claim 1, characterized in that the piston is made with a central channel connected by inclined channels with a piston hydraulic cavity, the first cylindrical surface of the piston is stepped with peripheral channels, and transverse channels are connected to the bottom of the groove connecting the central channel with the piston hydraulic cavity. 3. The apparatus according to claim 1, characterized in that the separators are made of the Central, peripheral and transverse channels connecting the Central channel with a piston hydraulic cavity. 4. The apparatus according to claim 1, characterized in that the second cylindrical surface of the piston is provided with peripheral channels with reverse valves located therein.