SU1481557A1 - Lubricant metering device - Google Patents

Abstract

The invention relates to mechanical engineering and can be used in the lubrication systems of metal-cutting machine tools and other equipment and allows to increase the reliability of work and save the lubricant. In the lubricant dispenser, which includes a housing with a cylindrical bore connected to the withdrawal channel, in which a portioning device interacting with a spring is placed, which includes a rod with two rows of radial channels connected with each other by an axial channel, and the inlet channel, the portion delivery device rod is stationary. The spool is made in the form of a glass with the formation of the inner chamber and the outer annular cavity, and two annular grooves connected to the mentioned radial channels are made on the stem, with elastic elastic rings placed in them far and near from the bottom of the glass. The rings are installed with the possibility of radial movement to the periphery, sequential sealing of the chamber with the far ring and connecting it with the proximal ring to the inlet channel connected to the axial channel. 1 il.

Description

The invention relates to mechanical engineering, namely to metering devices for liquid lubrication, and can be used in lubricating systems of metal-cutting machines, presses and other machines and mechanisms.

The purpose of the invention is to increase reliability by reducing the friction surfaces in the dispenser, which is provided by the formation of annular cavities between the movable elements.

The drawing shows the design of the dispenser.

The dispenser consists of a housing 1 in which a cylindrical bore 2 and a discharge channel 3 are made. On the stem 4, rigidly connected to the housing 1, there is a cup 5, which forms with the stem 4 an inner chamber 6, and with a bore 2 an outer annular cavity 7. On the stem 4 there are two annular grooves 8 and 9 connected to the radial channels 10 and 11, communicated by an axial Channel 12, which is connected to the channel 13 of the supply. The sealing elastic ring 14 furthest from the bottom of the cup 5 is placed in the groove 9. Installed with a gap in the chamber 6 and the inner diameter of the groove 9, it contacts the side surfaces of the groove 9 throughout its radial movement. The sealing elastic ring 15 located near the bottom of the beaker 5 is placed in the groove 8 and is fitted with a tight fit along its inner diameter, closing the outlets of the radial channels 10. The groove 8 profile is made expanding in the radial direction, which allows for clearance when moving the ring 15 to the periphery. between the ring 15 and the groove 8. The spring 16 is installed with emphasis in the housing 1 and the bottom of the glass 5.

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Between the housing 1 and the stem 4 there is a gasket 17 regulating the stroke of the cup 5.

The dispenser works as follows.

In the initial position, the cup 5 is pressed by the spring 16 to the rod 4. The chamber 6 is connected with the cavity 7 by the ring 14 and is cut off from the feed channel 13 by the ring 15.

With increasing pressure in the supply line, to which the metering device connects the inlet channel 13, the pressure in the axial channel 12 rises in the radial channels 10 and in the groove 9 along the radial channels 11. Because of this pressure on the inner surface of the ring 14, the latter moves in the radial direction, without losing contact with the side surfaces of the groove 9, and rests in the cup 5, thereby sealing the chamber 6, interrupting its connection with the cavity 7. Thereafter, increasing pressure, acting on the ring 15 along the radial channels 10, causes the radial moving the ring 15, in which, without touching the cup 5, it forms a gap in the groove 8. Through this gap, the oil from the feed channel 13 through the axial channel 12 and the radial channels 10 enters the chamber 6, and, overcoming the resistance of the spring 16 and The back pressure of the consumer, with which the dispenser connects the drain channel 3, lifts the glass 5, displaces the oil from the bore 2 through the drain pipe 3. At the end of the stroke, the cup 5 abuts against the housing 1 and the oil is pushed out onto the consumer lubricant, and the dose of lubricant is equal to the volume of incoming oil into the chamber 6.

When the pressure in the supply line decreases, the pressure in the supply channel 13, the axial channel 12 and the radial channels 10 and 11 decreases. At the same time, the ring 15 first returns to its original position due to tension and closes the outputs of the radial channels 10 in the groove 8, thereby compartment chamber 6 from the feed channel 13. In

Further, from hydrostatic imbalance due to the pressure drop in the groove 9, the ring 14 under the action of pressure in the chamber 6 returns to its original position and moves away from the cup 5, thereby jointly the chamber 6 with the cavity 7 and with the bore 2. The pressure in them is equalized and under the action The springs 16 cup 5 is fully lowered into the rod 4, displaced along the previously received oil from the chamber 6 into the bore 2. The cycle of the dispenser is completed and resumes with the next increase in pressure in the supply line.

Claims (1)

Invention Formula A lubricant dispenser comprising a housing with a cylindrical bore and inlet and outlet channels, a batch feed device installed in the bore, comprising rods with two rows of radial channels interconnected by an axial channel, and a spring-loaded slide valve mounted on the rod with the possibility of alternately opening radial channels moving the spool from one extreme position to the other, characterized in that, in order to increase reliability by reducing the number of friction surfaces, the rod is made stationary, annular grooves are made in the exit of the radial channels, in which elastic rings are installed with the possibility of radial movement, the supply channel is connected to the axial channel of the rod, the spool is made in the form of a glass, while the elastic ring closest to the supply channel is installed in the groove with an internal diameter clearance and with the possibility of contact with the side surfaces of the groove, the other ring is fitted with a strain on the inner diameter, and the profile of the groove of this ring is made expanding in the radial direction.