RU177025U1 - Shock knot - Google Patents

Abstract

The utility model relates to the field of hydrodynamics, hydraulics and mechanical engineering, where it can find application in devices for various purposes using the effect of water hammer, as well as heat supply, where it can be used to create pulsed fluid motion in relation to the intensification of heat transfer in thermal power plants. The technical result is achieved due to the fact that the shock assembly includes a hollow body with inlet and outlet openings for the expiration of the working medium, a shock valve rigidly fixed to the rod mounted in the sleeve with the possibility of reciprocating motion. Two additional coaxial holes are made in the hollow body, the sleeve is made with through channels for the flow of the working medium along the rod. The design further comprises a shaft with a cam, a spring, a retaining ring, a centering plug and a guide sleeve. The sleeve is rigidly connected to the inlet of the hollow body. The shock valve is located on the input side of the working medium into the through channels of the sleeve. The spring is mounted on the rod and secured to it by a circlip on the outlet side of the working medium from the through channels of the sleeve. The shaft is mounted inside the hollow body with the possibility of rotational movement, where one end of the shaft is inserted into the centering plug fixed in the first additional hole of the hollow body, the second end of the shaft is led outside the hollow body through the guide sleeve installed in the second additional through hole of the hollow body. The cam of the shaft is connected to the stem with the possibility of converting its rotationally sliding motion into reciprocating motion of the rod. As a result of using this design, the stability of the shock assembly is increased, since the phase of opening and closing of the shock valve is determined only by the position of the cam during rotation of the shaft and does not depend on flow working environment, it is possible to control the frequency of generation of pulses of the amount of movement of the working medium regardless of its flow through the device etsya problem of obtaining a predetermined value of pressure increase at the moment the water hammer in the working medium at a wide range of its flow. The utility model allows you to create the design of the shock node with the ability to control the frequency of generation of pulses of the amount of movement of the working medium, regardless of its flow rate through the technical device. 1 ill.

Description

The utility model relates to the field of hydrodynamics, hydraulics and mechanical engineering, where it can find application in devices for various purposes using the effect of water hammer, as well as heat supply, where it can be used to create pulsed fluid motion in relation to the intensification of heat transfer in thermal power plants.

Known shock node, comprising a cylindrical body with two inlet and outlet openings, two shock valves, while the inlet openings are opposite and made coaxially along the centering rod mounted in the cylindrical body on the bushings with shock valves rigidly mounted on its ends located above the inlet openings , a movable saddle is screwed into one of the inlets, connected by a worm gear with an adjusting screw (RU 114129, IPC F24D 3/02, publ. 10.03.2012).

The disadvantages of the known design of the shock node are its relatively low stability at low flow rates, as well as the violation of the phases of the alternate opening of the shock valves during operation of the device.

The closest in technical essence to the proposed technical solution is the design of the shock node of the vertical-translational type, where the poppet shock valve makes a vertical-translational movement along some guiding device. The design of the shock assembly selected for the prototype comprises a hollow body with inlet and outlet openings, a shock valve, a stem and a sleeve, the shock valve being located above the inlet and rigidly fixed to the rod mounted in the hollow body through the sleeve with the possibility of reciprocating motion ( Hovsepyan V.M. Hydraulic ram and ram installations / V.M. Hovsepyan. - M.: Mechanical Engineering, 1968. - 124 p., - p. 58, 65, Fig. 25, 26).

The disadvantages of the known solutions are the relatively slow closing of the shock valve, as well as the inability to control the moment of generation of pulses of the amount of movement of the working medium without changing its flow rate through the shock node.

The technical result consists in the ability to control the frequency of generation of pulses of the amount of movement of the working medium in the shock node, regardless of its flow rate.

The technical result is achieved due to the fact that the shock assembly includes a hollow body with inlet and outlet openings for the expiration of the working medium, a shock valve rigidly fixed to the rod mounted in the sleeve with the possibility of reciprocating motion. Two additional coaxial holes are made in the hollow body, the sleeve is made with through channels for the flow of the working medium along the rod. The design further comprises a shaft with a cam, a spring, a retaining ring, a centering plug and a guide sleeve. The sleeve is rigidly connected to the inlet of the hollow body. The shock valve is located on the input side of the working medium into the through channels of the sleeve. The spring is mounted on the rod and secured to it by a circlip on the outlet side of the working medium from the through channels of the sleeve. The shaft is mounted inside the hollow body with the possibility of rotational movement, where one end of the shaft is inserted into the centering plug fixed in the first additional hole of the hollow body, the second end of the shaft is led outside the hollow body through the guide sleeve installed in the second additional through hole of the hollow body. The cam of the shaft is connected to the rod with the possibility of converting its rotationally sliding motion into the reciprocating motion of the rod.

The drawing shows the design of the shock assembly.

The shock assembly includes a hollow body 1 with input 2 and output 3 openings for the expiration of the working medium. The shock valve 4, rigidly mounted on the stem 5, mounted in the sleeve 6 with the possibility of reciprocating motion. In the hollow body 1, two additional coaxial holes 7 and 8 are made. The sleeve 6 is made with through channels 9 for the outflow of the working medium along the rod 5. The structure further comprises a shaft 10 with a cam 11, a spring 12, a lock ring 13, a centering plug 14 and a guide sleeve 15. The sleeve 6 is rigidly connected to the inlet 2 of the hollow body 1. The shock valve 4 is located on the side of the working medium in the through channels 9 of the sleeve 6. The spring 10 is mounted on the rod 5 and secured to it by a locking ring 13 from the side of the working medium and from the through channels 9 of the sleeve 6. The shaft 10 is mounted inside the hollow body 1 with the possibility of rotational movement, where one end of the shaft 10 is inserted into the centering plug 14, mounted in the first additional hole 7 of the hollow body 1, and the second end of the shaft 10 is brought out of the hollow body 1 through a guide sleeve 15 mounted in a second additional through hole 8 of the hollow body 1. The cam 11 of the shaft 10 is connected to the rod 5 with the possibility of converting its rotary-sliding movement into reciprocating motion of the rod a 5.

The shock node operates as follows. First, they provide the connection of the free end of the sleeve 6 with the source (not shown) of the working medium supply, and the outlet 3 with the receiver (not shown) of the working medium. The shaft 10 from the outside of the hollow body 1 is connected to a source of rotational motion (not shown in the drawing), which, in order to be able to control the frequency of generation of pulses of the amount of movement of the working medium, must be able to change its own speed. For example, it can be an electric motor, the shaft rotation frequency of which is controlled by a frequency converter (not shown in the drawing), etc. In this way, the shaft 10 is rotated in the centering plug 14 installed in the first additional hole 7 of the hollow body 1, and the guide sleeve 15 installed in the second additional hole 8 of the hollow body 1. In this case, the cam 11 is connected to the shaft 10. the supply of the working medium through the hollow body 1 from its source to the receiver. When the cam 11, which is made in the form of an involute, is rotated, the rod 5 is reciprocated in the sleeve 6 and the through channels 9 are opened and closed in the sleeve 6 by the shock valve 4, which is rigidly fixed to the stem 5. The impact valve 5 is closed by the action of a spring 12 in tension, which is mounted on the rod 5 by means of a locking ring 13, as well as a high-pressure head of the working medium. Thus, the working medium, getting into the sleeve 6, passes through the through channels 9 when the shock valve 4 is open and enters the inlet of the working medium 2 of the hollow body 1, and then leaves it through the outlet 3. In this case, the working medium is accelerated. for the subsequent creation of an impulse of the amount of its movement. At the point in time when the spatial position of the cam 11 makes it possible to close the through channels 9 in the sleeve 6 by the shock valve 4, a hydraulic shock will occur, the energy of which can be used depending on the field of application of the shock assembly. After the spatial position of the cam 11 during the rotation of the shaft 10 provides the subsequent opening of the through channels 9 in the sleeve 6 by the shock valve 4, the process of generating a water hammer will be repeated in the sequence described above.

As a result of using the proposed technical solution:

the stability of the shock assembly increases, since the phase of opening and closing of the shock valve determines only the position of the cam during rotation of the shaft and does not depend on the flow rate of the working medium;

it is possible to control the frequency of generation of pulses of the amount of movement of the working medium regardless of its flow rate through the device;

the task is to obtain a given pressure increase at the time of the hydraulic shock in the working medium with a wide range of changes in its flow rate.

Claims (1)

Impact assembly, comprising a hollow body with inlet and outlet openings for the expiration of the working medium, a shock valve rigidly fixed to the rod mounted in the sleeve with the possibility of reciprocating movement, characterized in that two additional coaxial holes are made in the hollow body, the sleeve is made with through channels for the flow of the working medium along the rod, and the design further comprises a shaft with a cam, a spring, a retaining ring, a centering plug and a guide sleeve, and the sleeve is rigidly connected on with the inlet of the hollow body, the shock valve is located on the side of the working medium in the through channels of the sleeve, the spring is mounted on the rod and secured to it by a locking ring from the side of the working medium from the through channels of the sleeve, the shaft is mounted inside the hollow body with the possibility of rotational movement where one end of the shaft is inserted into the centering plug fixed in the first additional hole of the hollow body, the second end of the shaft is brought out of the hollow body through the guide sleeve installed in the second additional through hole of the hollow body, and the cam of the shaft is connected to the rod with the possibility of converting its rotational-sliding motion into the reciprocating motion of the rod.

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