SU57955A1 - Steam distribution mechanism for direct-action machines - Google Patents

Description

The present invention relates to the already known automatic steam distribution mechanisms for direct action machines using a single steam distribution organ of the type of a symmetric multi-disc valve that does not have a mechanical connection to the machine's piston and is aimed at further improving them with regard to ensuring uninterrupted operation with an uncomplicated device. For this purpose, in the proposed steam distribution mechanism for air pumps, the middle disk has a smaller diameter compared with the diameters of the extreme disks. To move the spool in the event of its stopping in the middle position, the middle disk is provided with channels that serve to supply steam to the extreme cavities of the spool box.

In FIG. 1 shows schematically the arrangement of the steam distribution mechanism, corresponding to the downward stroke of the high-pressure cylinder, FIG. 2 - the same with the course of the piston up;

FIG. 3 and 4-version of the mechanism with the use of three-symmetrical spool.

The steam distribution mechanism is made in the form of a two-plate symmetric spool (Figs. 1 and 2) located horizontally in a chamber integral with the high pressure cylinder cover. At both ends of the spool there are two disks, and only four disks 7, 8, 10, 11 of the same diameter; middle spool disc 9 has a smaller diameter.

The steam distribution chamber is divided into five spool discs into six cavities, numbered in the drawing in order from left to right from 1 to VI. With steam cylinders, the chamber is connected by channels, shown in the diagram by dotted lines, numbered from 12 to 17; in addition, the chamber has a supply of fresh steam by channel 18 and two openings 19 and 20 for communication with the atmosphere.

In FIG. 1, the spool is in the extreme right position; wherein

steam distribution is performed by the spool as follows. Fresh steam from channel 18 enters the cavity ///, and from here channel 14 into the upper half of the high-pressure cylinder, causes the piston to move downwards. At the same time, from the lower half of the high-pressure cylinder, intermediate-pressure steam flows through channel 15 into cavity IV, and from there through channel 17 into the lower half of low pressure cylinder, causing its piston to move upwards. The exhaust steam leaves the upper half of the low pressure cylinder through channel 16 through the cavity // and hole 19 into the atmosphere.

At the approach of the piston, the high-pressure cylinder to the lowest position, the piston opens the hole 21 (Fig. 1), and the fresh steam from the upper cavity of the cylinder through this hole and the channel 13 enters the cavity the pressure of the fresh steam on the pistons 7 V. 11 is mutually balanced, and the spool begins to move to the left due to the different values of vapor pressure in the cavities /// and IV.

In order to prevent the spool from stopping until its transition to the extreme left position at the moment when the cavity /// is separated from the channel of fresh steam and the cavity (I) begins to communicate with this channel, there are channels 23 24 in the spool .

Steam entering channels 23 and 24 simultaneously enters both cavities of the high-pressure cylinder. In this case, two cases are possible: either equal pressures are created in both cavities or these pressures will be different. In the first case, the piston cylinder moves down due to the difference in working areas above and below the piston (the working area from the bottom is equal to the working area from the top minus the cross-sectional area of the rod). In the second case, the spool passes into one of the extreme positions due to the presence of an overweight in the value of vapor pressure on one side. Thus, in either case, the possibility of stopping the valve in the middle position is excluded.

In the leftmost position (Fig. 2), the spool produces steam distribution as follows. Fresh steam from the IS channel enters the cavity IV, and from there channel 15- into the lower half of the high-pressure cylinder, causes the piston to move upwards. From the upper half of the high-pressure cylinder, the intermediate-pressure steam flows through channel 14 into the cavity ///, and from there, via channel J6 to the upper half of the low-pressure cylinder, causes its piston to move downwards. The exhaust steam exits the lower half of the low pressure cylinder through channel 17 through cavity V and hole 20 to the atmosphere.

In view of the complete symmetry of the mechanism, the spool is relocated to the extreme right position when the piston approaches the upper position also happens quite similarly to rearranging it from the extreme right to the extreme left position, which is described above.

In the embodiment of the steam distribution mechanism of FIG. 3 and 4 a three-disk symmetric spool is applied; its middle disk 6 has a smaller diameter than the diameters of the extreme disks 7, 8 and the latter are of the same diameter.

The diagram shows the steam distribution mechanism in two positions corresponding to the stroke of the steam cylinder. In the diagram of FIG. 3 spool occupies the leftmost position. Fresh steam from the channel (S) enters the cavity ///, and from here channel J4 into the lower half of the cylinder, causes the piston to move upwards. At the same time, from the upper half of the cylinder, the exhaust steam escapes into the atmosphere through channel J and cavity I. The spool is securely held in this position, since on the right side he ends up steam and on the left side it is connected to the atmosphere. When the piston 4 approaches the upper extreme position, the piston opens channel 5, and fresh steam from

the lower cavity of the cylinder through this channel enters the cavity VI; the pressure of the fresh steam on the discs 7 and 8 is mutually balanced, and the spool begins to move to the right, due to the different value of the vapor pressure in the cavities // and ///.

In order not to stop the spool before it goes to the extreme right position at the moment when the cavity /// is separated from the channel of fresh steam, and the cavity // begins to communicate with this channel, in the spool there are as in the first case (Figs. 1 and 2), channels 9, 10. Through these channels, fresh steam begins to flow into cavity VI directly from channel 18 even before fresh steam enters the cavity //. Cavities V and III already begin to communicate with the atmosphere through channels 12 and 14 and this ensures that the spool reaches the extreme right position (Fig. 4).

In the extreme right position of the spool, fresh steam from the channel / 8 enters the cavity //, and from there, channel G into the upper half of the cylinder, causes the piston 4 to move downwards; from the lower half of the cylinder, the exhaust steam enters the atmosphere through channel 14 and the cavity ///.

The subject matter of the invention.

The steam distribution mechanism for a direct-action compound-compound, using one multi-disk symmetric spool, rearranged on both sides with steam, characterized in that its middle disk is smaller in diameter and equipped with channels 23 and 24 for steam supply into the extreme cavities of the spool box in order to move the spool in the event it stops in its middle position.

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