SU1114486A1 - Pulsing head - Google Patents

Abstract

PULSE HEAD, comprising a housing with a working cavity, a valve that forms a valve over the valve, and a shock absorber placed in the cavity above the valve, so that, in order to increase the durability, the shock absorber is made in the form of an elastic chamber fixed to the cover and placed with a gap relative to the valve, while the cavity of the elastic chamber is communicated with nadklapannoy cavity. P 4 i4 CX) 05

Description

The invention relates to foundry, in particular, to devices for sealing and knocking out molds with compressed air.

Known pulse head, containing the body with krppkoy, in the cavity of which is placed a stepped valve that blocks the outlet 1}

The disadvantage of the pulse head is the low durability associated with the accelerated movement of the stepped valve to the extreme upper position, which ends with the blow of this valve into the cap. If we take into account the mass of the valves, which is about ten kilograms, the TQ will become obvious the force of its impact on the lid.

The closest to the technical essence and the achieved effect to the invention is a pulse head, comprising a housing with a working cavity and a stepped valve that forms an over-valve cavity with a ratchet and a shock absorber located in the over-valve cavity. At the same time, a spring 2j is installed between the valve and the cover.

The spring installed between the valve and the flap eliminates the blow of the valve against the valve, but it prevents the valve from accelerating, which is so necessary for the instantaneous release of compressed air from the working cavity. Moreover, having risen to the extreme upper position, the valve cannot remain stationary, since limiting its further upward movement, has at this moment the maximum force, therefore the valve moves downward and with impact hits the saddle. Such shocks are repeated with each pulse and reduce the durability of the pulse head,

The purpose of the invention is to increase the durability of the pulse head.

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The goal is achieved by the fact that a pulse head, comprising a housing with a working cavity, a valve that forms a valve over the valve and a shock absorber placed in the valve cavity, the shock absorber is in the form of an elastic chamber fixed on the cover and placed with a gap relative to the valve, with

This cavity elastic chamber communicated with nadklapannoy cavity.

Due to the elastic chamber located in the supravalvular cavity, the valve moves to the highest position without impact. Moreover, the elastic chamber does not impede the accelerated valve lift, since there is a gap between them.

And due to the fact that the cavity of the elastic chamber communicates with the valve valve, a sharp valve lift does not compress the elastic chamber, since it contains compressed air. At the same time, the elastic chamber, limiting the further movement of the valve up, does not push it down due to the fact that simultaneously with the release of compressed air from the valve cavity, its pressure also decreases in the elastic chamber.

The drawing shows a pulse head, a slit.

The pulse head comprises a housing 1 with a working cavity 2, in which a stepped valve 3 is placed, which forms an over-valve cavity 5 with a crush 4 and blocks the exhaust port 6.

In the over-valve cavity 5 with a gap relative to the stepped valve 3, an elastic chamber 7 is placed, which is fixed to the lid 4 by means of a disk 8. The cavity 9 of the elastic chamber 7 communicates with the valve valve 5 with a cross-sectional area of 0.5-0.9 the cross-sectional area of the orifice of the nozzle 11 intended to supply compressed air to the pulse head and to discharge it from the over-valve cavity 5.

The over-valve cavity 5 communicates with the working cavity 2 by radial nozzles 12, the outlets of which are located in the annular grooves 13 on the outer surface of the annular protrusion 14 of the rim 4 and are covered by toroid-shaped elastic elements 15.

The material for the manufacture of the elastic chamber 7 is rubber or rubber-cord.

The device works as follows.

To charge the working cavity 2, through the pipe 11, compressed air is supplied to the above-valve cavity 5, which, acting on the stepped valve 3, moves it downward, blocking the exhaust port 6. From the adhered cavity 5, the compressed air enters the cavity 9 through the pipe 10, as well as the toroidal elastic elements 15, from the outlets of the radial nozzles 12, pass through them into the working cavity 2. After completing the filling of the working cavity 2 with compressed air, the toroidal elastic elements 15 occupy the initial position. The compressed air supply to the pulse head is stopped. Dp of the production of a pulse, compressed air from the suprapalar cavity 5 is directed through a pipe 11 to a discharge line (not shown). Simultaneously with the release of compressed air from the upper valve cavity 5, its pressure in the cavity 9 of the elastic chamber 7 decreases. As a result of a drop in the pressure of the compressed air in the super valve valve, this is due to the difference in the areas of the piston and gate parts of the stepped valve 3, as well as superior pressure of the compressed air in The working cavity 2 The stepped valve 3 moves upwards, opening up the opportunity for the compressed air to rush out of the working cavity 2 through the exhaust hole 6 to the molding sand (not shown). Due to the fact that there is a gap between the elastic chamber 7 and the step valve 3, the rise of the latter occurs rapidly, which is a good circumstance for the instantaneous release of compressed air from the working cavity 2. Having reached the elastic chamber 7, the step valve 3 senses the resistance of the compressed air in it and therefore the speed of its movement begins to fall. Restricting the further movement of the stepped valve 3 up, the elastic chamber 7 does not push it down, because simultaneously with the release of compressed air from the valve valve 5, its pressure decreases in the cavity 9 of the elastic chamber 7. Moreover, the pressure in the cavity 9 of the elastic chamber 7 decreases slowly compared to with the pressure drop of the compressed air 6 of the over-valve cavity 5. This is due to the fact that the cavity 9 of the elastic chamber 7 communicates with the valve valve 5 with a tube 10 with a cross-sectional area of 0.5 0, 9 The cross-sectional area of the opening of the nozzle 11. An increase in the limit of 0.9 leads to simultaneous release of compressed air from the valve chamber 5 and cavity 9 of the elastic chamber 7. This is not recommended to prevent the elastic chamber from being crushed by a 7-speed valve. A reduction in the limit of 0.5 leads to a J slowing down the output of compressed air from the cavity 9 of the elastic chamber 7. This is undesirable in order to avoid pushing valve 3 down. Thus, due to the fact that an elastic chamber 7 is placed in the above-valve cavity 5 with a gap relative to the stepped valve 3, the cavity 9 of which is connected to the valve valve 5, the blows of the stepped valve 3 are eliminated.

Claims (1)

PULSE HEAD, comprising a body with a working cavity, a valve forming a supravalvular cavity with a cover, and a shock absorber located in the supravalvular cavity, which requires that, in order to increase durability, the shock absorber is made in the form of an elastic chamber, fixed on the cover and placed with a gap relative to the valve, while the cavity of the elastic chamber is in communication with the supravalvular cavity. . 1 Ί114486 1