RU125635U1 - PISTON PUMP COMPRESSOR - Google Patents

Abstract

1. A piston pump-compressor, comprising a crankcase, cylinder and piston, dividing the cylinder into upper, compressor and lower pump cavities, which are connected to the source and consumer of gas and liquid, respectively, using self-acting reverse gas and liquid valves, characterized in that the piston made by tronkovy, and the crankcase is part of the volume of the pumping cavity and is connected to self-acting fluid check valves. 2. A piston pump-compressor according to claim 1, characterized in that the cylinder is provided with a hollow jacket connected to the upper part of the crankcase, and a liquid discharge valve is installed in the upper part of the jacket.

Description

The utility model relates to the field of pump and compressor engineering and can be used to create volumetric reciprocating machines designed to compress and supply liquids and gases to the consumer simultaneously or alternately.

Known piston pump-compressor containing a cylinder and a differential piston with a rod, the lower part of the cylinder is filled with liquid and the upper with gas (see, for example, the USSR AS No. 1078126 according to the application 3513877 / 25-06, CL F04B 39/06, publ. 07.03.84, Bull. No. 9).

A piston pump-compressor is also known, comprising a crankcase, a cylinder and a piston dividing the cylinder into an upper compressor and lower pump cavity, which are connected to a source and consumer of gas and liquid, respectively, using self-acting reverse gas and liquid valves (see RF patent No. 118371, MKI F04В 19/06 from 07/20/2012).

A disadvantage of the known designs is the large dimensions along the axis of the piston and the tendency to cavitation and water hammer in the pump cavity with a high frequency of reciprocating movement of the piston (of the order of 20-25 Hz or more), characteristic of low-speed reciprocating compressors, which also generally reduces the reliability of the design and increases its material consumption, if high efficiency of the pump-compressor is required, due to the forced reduction of the frequency of the reciprocating motion of the piston. In addition, in known designs, especially at low productivity, the active removal of heat from the compressible gas requires additional power consumption for the fan, which reduces the efficiency of the machine. This is especially important when using a pump compressor in mobile systems and when placing it in the volume of vehicles, for example, in the engine compartment of a car.

The objective of the utility model is to increase the reliability and efficiency of the piston pump-compressor and reduce its weight and dimensions.

This problem is solved by the fact that the piston is made of a throttle, and the crankcase is part of the volume of the pump cavity and is connected to self-acting fluid return valves.

The cylinder of the pump-compressor may have a hollow jacket, which is connected to the upper part of the crankcase, and a liquid discharge valve is installed in the upper part of the jacket.

The essence of the proposed technical solution is illustrated by the drawing (Fig.), Which schematically shows the axial section of the pump-compressor.

The compressor pump consists of a crankcase 1, in which a liquid suction valve 2 is installed. In the crankcase 1 there is a drive shaft 3 with a crank 4 and a connecting rod 5 of the tron piston 6 having a gas piston cavity 7 and separating the cylinder 8 into the upper compressor cavity 9 and the lower pump cavity 10, which is directly connected to the crankcase 1, i.e. the crankcase 1 is part of the volume of the pump cavity. The cylinder 8 has a jacket 11, in the upper part of which there is a liquid discharge valve 12 connected through the jacket 11 and the hole 13 to the crankcase 1. The compressor cavity 9 has self-acting check valves: 14 - discharge and 15 - suction. The crankcase 1 is connected through a suction valve 2 to a fluid source and through a valve 12 to a fluid consumer (shown by arrows). The compressor cavity 9 is connected by valves 15 and 14, respectively, with the gas source and consumer (shown by arrows). Piston rings 16 are used to seal the gap between the piston 6 and the cylinder 8. In figure 1, the liquid is indicated by a wavy hatching.

Pump compressor operates as follows.

When the drive shaft 3 is rotated with the crank 4 due to the connecting rod 5 mounted on the crank 4, the reciprocating movement of the tron piston 6 occurs. The volume of the compressor cavity 9 and the total volume of the pump cavity 10, the sub-piston gas space 7 and the crankcase 1 alternately increase and decrease.

The change in the volume of the compressor cavity leads to the absorption of gas through the suction valve 15 (piston 6 goes down to bottom dead center), its compression and pumping through the discharge valve 14 to the consumer (piston 6 goes up to top dead center).

When the piston moves down from the top dead center, the total volume of the cavities 7, 10 and 1 decreases, however, in fact, the change in volume occurs only in the cavity 7 due to the high ability of the gas to change its volume with increasing pressure, in contrast to a liquid that is practically incompressible. This leads to a gradual increase in gas pressure in the cavity 7 and, respectively, in the crankcase 1 and the pump cavity 10, until it exceeds the pressure of the consumer fluid, after which the valve 12 smoothly opens and begins the displacement of fluid from the crankcase 1 through the hole 13 and shirt 11 to the consumer. During the entire process of fluid injection, the gas pressure in the cavity 7, as in the cavity 10 and the crankcase 1, remains close to the pressure of the consumer fluid. When the piston 6 approaches the bottom dead center, the process of displacing the liquid from the crankcase 1 ends.

When the piston 6 moves upward, the total volume of the cavities 7, 10 and the crankcase 1 increases, which actually occurs only due to the cavity 7, however, this change does not lead to a sharp drop in pressure in these cavities, as in a conventional pump, and the pressure gradually decreases, due to a gradual decrease in pressure in the cavity 7 during the expansion of gas in it, which leads to a smooth closure of the liquid discharge valve 12.

Further, the volume of the cavity 7 continues to increase, and the pressure in it gradually decreases (accordingly, the pressure of the liquid in the crankcase 1 and cavity 10 gradually decreases) until it falls below the pressure of the liquid source, which leads to a smooth opening of the suction liquid valve 2 and the beginning replenishment of the total volume of crankcase 1 and cavity 10. This replenishment occurs until the piston 6 arrives at top dead center and continues until the pressure in the cavity 7 becomes equal to or greater than the pressure of the fluid source (at the beginning of the stroke 6 rshnya down), which results in a smooth closure of the valve 2, as when the drive (crankshaft) shaft is rotated by a significant angle (5-10 degrees), the change in volumes in a piston machine with a crank mechanism is very small when the piston passes dead points.

Then the cycle of the pump-compressor is repeated.

It should be noted that in the described design, the injection of fluid occurs through the jacket 11, surrounding the cylinder 8 and cooling it, taking away the heat released during compression of the gas in the compressor cavity 9, which brings the compression process closer to isothermal and increases the efficiency of the compressor cavity.

However, even if the fluid is pumped through the pressure valve installed directly in the crankcase 1, it is all the same - the constant change of fluid in the crankcase and its passage through the parts that make up the piston-cylinder group promotes the active removal of the heat of compression transferred by the gas to the compressor parts due to their thermal conductivity , which also helps to increase the efficiency of the pump compressor.

The soft operation of the valves and the absence of a sharp change in fluid pressure due to the use of the tron piston and the crankcase as a part of the pump cavity, can significantly increase the frequency of movement of the piston, bringing it to the frequencies characteristic of compressor machines. This allows you to significantly reduce the dimensions of the pump compressor (approximately by 30-50%) and its mass, thereby obtaining a compact piston compressor, increasing the reliability, which mainly depends on the reliability of the valves, and increasing efficiency by improving the thermodynamics of the compressor cavity.

Claims (2)

1. A piston pump-compressor, comprising a crankcase, cylinder and piston, dividing the cylinder into upper, compressor and lower pump cavities, which are connected to the source and consumer of gas and liquid, respectively, using self-acting reverse gas and liquid valves, characterized in that the piston made by tronkovy, and the crankcase is part of the volume of the pumping cavity and is connected to a non-return self-acting fluid valves. 2. The piston pump-compressor according to claim 1, characterized in that the cylinder is equipped with a hollow jacket connected to the upper part of the crankcase, and a liquid discharge valve is installed in the upper part of the jacket.

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