RU674U1 - Self-oscillating vibration exciter - Google Patents

Abstract

1. Self-oscillating vibration exciter, comprising a housing with an energy supply channel, a drummer located in the housing, cut-off and exhaust valves, and elastic diaphragms forming different forward and reverse cameras with the housing and drummer, and a channel connecting the forward and reverse cameras is made in the drummer the passage, and the exhaust channel from the reverse chamber to the exhaust silencing chamber associated with the atmosphere, characterized in that the exhaust silencing chamber is made in the housing opposite to the reverse chamber and an exhaust valve is installed thereto with the possibility of interaction with the exhaust channel and the inner end surface of the housing, and a cut-off valve is installed in the return chamber with the possibility of interaction with the channel connecting this chamber to the forward-stroke chamber and with the corresponding end surface of the housing, with one elastic diaphragm installed as a common wall of the forward and reverse cameras, and the second elastic diaphragm is installed in the forward camera and an inlet channel is located between these diaphragms. 2. The vibration exciter according to claim 1, characterized in that a part of the end surface of the housing interacting with the valve is made in the form of a fixed or adjustable stop.

Description

Self-oscillating vibration exciter

The proposed utility model relates to vibration technology, specifically to pneumatic vibration exciters, intended for use in mechanisms for the production of building materials, in the mining industry, as well as in other industries where vibration is used ..

 Known pneumatic vibration exciter containing a housing, inlet and outlet channels, a drummer with an axial through channel, elastic cuffs forming a forward and reverse chamber, inlet and outlet valves with a housing and a drummer, each of which is made in the form of a rod, one end of which is installed in the axial channel of the hammer, and the second end is in the body. During operation, the inlet valve periodically connects the forward and reverse chambers to the axial channel of the striker, and the exhaust channel periodically connects the reverse chamber to the atmosphere. Autosvid, No. 1748884, M.cl. B 06 B I / I8, 1989).

However, this vibration exciter is not reliable enough in view of the need for a sliding fit of the valves relative to the hammer, which during operation will be disturbed due to friction. In addition, the device has increased dimensions in the axial direction due to the placement of the inlet and outlet channels for supplying and discharging the working medium.

Closest in design to the claimed one is a pneumatic self-oscillating vibration exciter containing a housing with a striker and elastic guns with diaphragms forming different-sized forward and reverse chambers with them, a shut-off valve located in the forward-stroke chamber, and an exhaust valve installed in the cavity of the reverse-chamber through the channel made in the drummer. The exhaust of the energy carrier from the return chamber takes place through the exhaust channel into the exhaust silencing chamber and then into the atmosphere. The exhaust silencing chamber is made in the drummer in the form of a labyrinth gap with expansion cavities formed between

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drummer hoists (Autosvid. I4545I9, Mskl. V 06 V, I / I8, 1987).

A significant drawback of this vibration exciter is the complex design associated, in particular, with the implementation of the labyrinth gap in the drummer. It should also be noted that the need to place the inlet channel on the end surface of the housing increases the dimensions of the device in the axial direction.

Therefore, the proposed utility model is based on the task of creating a design of a vibration exciter that is simple in technical design and has relatively small dimensions in the axial direction and has increased reliability.

The problem is solved by the proposed new design of the vibration exciter due to a different arrangement of its main elements.

The inventive utility model of a self-oscillating vibration exciter, like well-known devices of a similar purpose, contains a housing with a drummer located in it, inlet and outlet channels for supplying and discharging a working medium, cut-off and exhaust valves, as well as elastic diaphragms that form two different sizes with the body and drummer cameras: a forward working chamber and a large reverse chamber. As in the prototype, in the drummer of the claimed utility model there is a channel connecting both chambers, and an exhaust channel that diverts energy from the return chamber. But, unlike the prototype, in the proposed model, the exhaust silencing chamber is located in the housing opposite to the reverse chamber and the exhaust valve is installed in it with the possibility of interaction with the inner end surface of the housing and the channel connecting the silencing chamber to the reverse chamber

move. Another valve (cut-off) is installed in the reverse-stroke chamber with the possibility of periodic interaction with the corresponding end surface of the body and with the drum channel connecting this chamber with the forward working chamber. Different location and elas gm,

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diaphragms, which reduced the size of the exciter due to the placement of the inlet channel on the side surface of the housing. One of the elastic diaphragms is installed so that it is a common wall for the forward and reverse cameras, and the second diaphragm is installed only in the forward / southward camera, i.e. This camera has two diaphragms, between which the inlet channel for supplying energy is located.

The inventive utility model allows the use of well-known disk and similar exhaust valves and cutoffs. In this case, there are possible options for the interaction of valves both directly with the upper surface of the body, and through stops made on these surfaces in the form of a fixed protrusion or adjustable stop.

The drawing shows the inventive self-oscillating vibration exciter. It has a housing I with a channel 2 for supplying energy. A hammer 3 with two elastic diaphragms 4 and 5 is placed in the housing, which, together with the housing and the hammer, form a forward chamber 6 and a reverse chamber 7. The chamber 7 is equipped with a chamber 7 for attenuation of exhaust noise associated with the atmosphere through the openings 9 of the housing. A shut-off valve 10 is located in the cavity of the back-up chamber 7, blocking the channel II, filled in the hammer 3 and connecting the chambers b and 7. In the cavity of the silencing chamber of the flopper 8 there is a flap valve: blade 12, which covers the exhaust channel 13, filled in the hammer 3 and connecting the chambers 7 and 8. The shutoff valve 10 periodically interacts with the stationary protrusion 14 of the housing, and the exhaust valve 12 with an adjustable stop 15 of the housing I.

This vibration exciter works as follows.

The energy carrier (compressed air) enters through the channel 2 into the forward chamber 6. Under pressure, the shutoff valve 10 moves towards the stop 14 and closes the channel II, sealing the chamber 6. Due to the pressure, the volume of the chamber b increases, moving the hammer 3 together with the valve 10 towards the stop 14. The exhaust valve 12 at this moment, abutting against the stop 15, does not block the exhaust channel 13 and the kame; - ,.

pa 7 is connected to the atmosphere through the chamber 8 and the holes 9. After the valve 10 interacts with the stop 14, the hammer 3 continues to move by inertia. This opens the channel II, connecting the chambers 6 and 7, a. valve 12 comes out of contact with uporbm 15 and seals chamber 7. The pressure in chambers b and 7 is equalized, because camera 7 is larger than camera b. Due to the difference in area, the drummer 3 changes the direction of movement. In this case, the valves Id and IZ continue to interact with the corresponding stops 14 and 15 in the reverse sequence: the valve 10 closes the channel П, then the valve 12 opens the channel 13, through which the energy carrier enters the exhaust silencing chamber 8 and then through the openings 9 in the housing I into the atmosphere . Then the cycle repeats.

Thus, it can be seen that the inventive self-oscillating vibration exciter has a fairly simple design and high reliability with small dimensions in the axial direction.

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The applicant applicant ,,, N.A. Radkevich

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Claims (2)

1. Self-oscillating vibration exciter, comprising a housing with an energy supply channel, a drummer located in the housing, cut-off and exhaust valves, and elastic diaphragms forming different forward and reverse cameras with the housing and drummer, and a channel connecting the forward and reverse cameras is made in the drummer the passage, and the exhaust channel from the reverse chamber to the exhaust silencing chamber associated with the atmosphere, characterized in that the exhaust silencing chamber is made in the housing opposite to the reverse chamber and an exhaust valve is installed thereto with the possibility of interaction with the exhaust channel and the inner end surface of the housing, and a cut-off valve is installed in the return chamber with the possibility of interaction with the channel connecting this chamber to the forward-stroke chamber and with the corresponding end surface of the housing, with one elastic diaphragm is installed as a common wall of the forward and reverse cameras, and the second elastic diaphragm is installed in the forward camera and an inlet channel is located between these diaphragms. 2. The vibration exciter according to claim 1, characterized in that a part of the end surface of the housing interacting with the valve is made in the form of a fixed or adjustable stop.