RU2578748C1 - Piston compressor with independent liquid cooling - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to compressor-building industry and can be used in compressors with independent liquid cooling. Compressor consists of cylinder 1 with piston 2 to make working volume 4, injection cavity 5, pressure valve 6, suction cavity 7, suction valve 8. Around working volume 4 there is liquid cooling jacket 9. Its lower part is connected to a source of cooling liquid in the form of circular jacket 10 via two channels 11 and 12. Upper part of cooling jacket 9 is connected by channel 13 with injection cavity 5. Due to fluid flow in cooling jackets 9 and 10 there is intensified a heat release from gas compression into the environment, which takes place without additional mechanical costs.

EFFECT: higher efficiency and reduced specific expenditures on production of compressed gas.

7 cl, 4 dwg

Description

The invention relates to the field of compressor engineering and can be used to create economical reciprocating compressors with autonomous liquid cooling of the cylinder-piston group.

Known vertical piston machine containing a crankcase, a cylinder with a piston placed in it with a drive mechanism with the formation of the working volume, a suction cavity connected to the gas source and with the working volume through the suction valve, and a discharge cavity connected to the gas consumer and the working volume through the discharge valve (see, for example, the book by BS Fotin, IB Pirumov, IK Prilutsky, PI Plastinin. “Piston compressors.” - L .: Engineering, 1987, p. 5, fig. . IN 1).

Also known is a vertical piston machine comprising a crankcase, a cylinder with a piston disposed therein with a drive mechanism to form a working volume, a suction cavity connected to a gas source and with a working volume through a suction valve, and a discharge cavity connected to a gas consumer and with a working volume through the discharge valve, and around the working cavity there is a liquid cooling jacket (see, for example, the book by BS Fotin, IB Pirumov, IK Prilutsky, PI Plastinin. “Piston compressors.” - L .: Engineering, 1987, pp. 185-185, Fig. 6.32).

The disadvantage of the first option is the impossibility of economically obtaining in one stage a high degree of pressure increase, because when using air cooling, it is impossible to remove a sufficiently large amount of heat from the compressible gas. In the second case, when the working cavity is washed by coolant, and there is the possibility of increasing the degree of pressure increase, the compressor design becomes cumbersome due to the need to have an additional coolant supply mechanism, which increases the mass of the compressor, complicates its design, increases its cost and increases overall costs gas compression capacity. All this taken together increases the present value of the compressed gas and reduces the overall efficiency of the compressor.

The objective of the invention is to reduce the present value of compressed gas and increase the overall efficiency of the compressor.

This problem is solved in that the lower part of the liquid cooling jacket is connected to a source of cooling liquid, and the upper part of the cooling jacket is connected by a channel to the discharge cavity, the source of cooling liquid can be made in the form of an additional annular jacket, which is connected to the bottom of the cooling jacket by a channel (or channels ) as a communicating sealed vessel and has cooling fins on its surface, in a cooling jacket with a small radial clearance relative to its outer and inner diameters a float having the shape of a flat ring can be installed, the lower part of the liquid cooling jacket can be connected to the ring jacket using at least two channels, each of which has at least one truncated cone sleeve, moreover, in one channel, the sleeve is mounted with its apex toward the cooling jacket, and in the other, with its apex towards the liquid source, the channel connecting the injection cavity to the upper part of the jacket may have an inlet located on the side of this cavity directly above the discharge valve, in the form of a truncated cone, with a large base directed towards this valve, the coolant source can be made in the form of a container partially filled with liquid, which is connected through a non-return valve and a heat exchanger to a buffer cavity, which is connected through a non-return valve with the upper part of the cooling jacket, and while the discharge cavity is connected to the upper part of the cooling jacket through the aforementioned buffer cavity and check valve.

The invention is illustrated by drawings.

In FIG. 1 schematically shows a vertical section of a compressor, with an additional annular jacket connected to the bottom of the cooling jacket as a communicating sealed vessel, in its original state.

In FIG. Figure 2 shows a similar section of the compressor in the operating state at the moment the piston was at bottom dead center at the beginning of the compression - injection process

In FIG. Figure 3 shows a similar section of the compressor in the operating state at the moment the piston approaches the top dead center during the discharge process.

In FIG. Figure 4 shows a schematic longitudinal section of a compressor with a coolant power source in the form of a container partially filled with coolant.

The compressor (Fig. 1-3) consists of a cylinder 1 with a piston 2 placed in it with a drive mechanism 3 (the rod of this mechanism is shown in the figure, the mechanism itself is not shown conventionally) with the formation of a working volume 4, a discharge cavity 5 connected to the gas consumer and with a working volume 4 through a discharge valve 6, and a suction cavity 7 connected to a gas source and with a working volume 4 through a suction valve 8, and around the working volume 4 there is a liquid cooling jacket 9, its lower part is connected to a source of coolant, filled in the form of an additional annular shirt 10 with cooling fins, through two channels 11 and 12 located opposite each other relative to the axis of the cylinder 1, and the upper part of the cooling jacket 9 is connected by a channel 13 with a discharge cavity 5. A sleeve 14 is installed in the channel 11 in the form of a truncated a cone rotated with its apex toward the source of fluid — an annular shirt 10, and in the channel 12 — a similar sleeve 15 turned with its apex toward the cooling jacket 9. At the top of the cooling jacket 9 there is a float 16 placed with a small radial clearance with respect to its outer and inner diameters and representing a flat ring. The channel 13 connecting the discharge cavity 5 with the upper part of the jacket 9 has an entrance from the side of this cavity located directly above the discharge valve 6, in the form of a truncated cone 17, with a large base directed towards this valve.

In the initial state, above the liquid in the jacket 9 there is a layer of air 18, and above the liquid in the jacket 10 there is a layer of air 19.

In FIG. 4 schematically shows a longitudinal section of a compressor in which the source of coolant is made in the form of a container 20 partially filled with liquid, which is connected through a non-return valve 21 and a heat exchanger 22 to a buffer cavity 23, which is connected through the non-return valve 24 to the upper part of the cooling jacket, and the injection cavity 5 is connected to the upper part of the cooling jacket 9 through the channel 13 and the aforementioned buffer cavity 23 and the check valve 24. In the tank 20 there is a gas layer 25 above the liquid, and a gas layer 26 in the cavity 23. there cool the spiral protrusion 27 along its axis, which causes the cooling liquid in the jacket to move downward rounding cylinder 1.

The compressor operates as follows (Fig. 1-3).

With a stationary piston (the compressor "stands", Fig. 1) and the absence of excessive pressure (in comparison with a gas source, for example, the atmosphere) in the injection cavity 5, the liquid in the jacket 10 is at the same level as the liquid in the jacket 9.

With the reciprocating movement of the piston 2, gas is sucked through the cavity 7 and valve 8 into the working cavity 4, is compressed in it and is pumped through the valve 6 and cavity 5 to the consumer, and the consumer pressure gradually increases, which leads to an increase in the average pressure in the cavity 5, which through the channel 13 enters the air layer 18, its pressure rises to the discharge pressure, and the liquid in the jacket 9 through the channel 11 enters the jacket 10, raising the level in it until the gas pressures in the layer 18 and in the compressible layer 19 are equal (Fig. 2).

During the piston stroke down (suction process, valve 8 is open), the pressure in the cavity 5, channel 13 and layer 18 stabilize and become equal to the pressure of the gas consumer

During the compression process (the piston goes up), when the pressure in the cavity 4 reaches the pressure of the gas consumer, the valve 6 opens, the pumping process begins (Fig. 3), and gas flows through the cavity 5 to the consumer. Due to the inevitable presence of hydraulic resistance of the discharge line, along which the gas reaches the consumer, the pressure in the cavity 5 rises above the consumer pressure during the injection process. This increased pressure in the channel 13 enters the layer 18, the pressure in it rises above the consumer pressure, and the liquid in the jacket 9 moves downward, raising the liquid in the jacket 10 until the pressures of the layers 18 and 19 are equal. The cone 17 stands directly in the flow of the injected gas and serves to further increase the pressure of the gas entering the channel 13 by converting part of the kinetic energy of the gas into potential pressure energy.

At the end of the injection process, when the piston 2 passes the top dead center, the valve 6 closes, the suction process with the open valve 8 begins, and during the entire suction process the pressure in the layer 18, channel 13 and cavity 5 is again stabilized to the consumer pressure, t. to. they are connected to each other, and during the entire process of suction, there is no gas movement in them. At the same time, the pressure decreases to the consumer pressure in the structural elements listed above, while a higher pressure remains in the layer 19, under which the liquid in the jacket 10 moves down, and in shirt 9, up. Then the cycle repeats.

In addition, due to the presence of conical bushings 14 and 15, which have different hydraulic resistance in the direction (when the fluid moves from the base of the cone to its top, it is smaller and vice versa), when the fluid rises in the shirt 9, it will flow more into this shirt through the sleeve 15 than through the sleeve 14, and when lowering the liquid from the shirt 9 will merge more down through the sleeve 14 than through the sleeve 15, because of which, in addition to the movement of the liquid in the shirt 9 "up-down", an additional circular motion fluid from the right p bashki 9 (on the drawing) into its left side and vice versa. And, accordingly, in the shirt 10, the liquid will flow from the left to the right when the liquid flows from the shirt 9, and vice versa - when the liquid flows into the jacket 9.

Thus, in this design, during each complete cycle (in one double stroke of the piston), the liquid in the jackets 9 and 10 makes a reciprocating and circular motion, which significantly increases the heat transfer coefficient of the compressed gas through the wall of the cylinder 1 and then through the fluid and the walls shirts 9 and 10 into the environment, which also contribute to the cooling fins of the shirt 10.

In the construction shown in FIG. 4, the principle of operation of which is similar to the above, in the process of pumping gas with increasing pressure in the cavity 5 above the pressure of the gas consumer, this pressure is transmitted through the channel 13 to the gas layer 26, which through the valve 24 squeezes the liquid from the cavity 23 into the jacket 9, where it spiral moves around the walls of the cylinder 1 down, and through the channel 11 enters the tank 20, compressing the gas layer 25, and is not able to pass through the valve 21, because behind it, in the heat exchanger 22, the liquid is under the pressure of the gas layer 26. At the end of the injection process, when the pressure in the cavity 5, channel 13 and the gas layer 26 stabilizes and becomes equal to the pressure of the gas consumer, the pressure of the gas layer 25, which is higher than the pressure of the gas consumer, squeezes the liquid from the tank 20 through the valve 21, the heat exchanger 22, where it transfers the heat taken from the surface of the cylinder 1 to the cavity 23 until the pressure in the gas layer 25 becomes equal to the pressure of the gas layer 26, which is equal to the pressure of the gas consumer.

That is, in this design intermittent movement of the coolant in a closed ring is carried out, during which the fluid removes heat from the compressible gas, transferring it to the environment and increasing the efficiency of the compressor cycle.

Thus, in the proposed design variants of the compressor, there are no special mechanisms for pumping liquid through the cylinder cooling jacket, and, accordingly, there are no mechanical losses associated with their operation, liquid cooling of the cylinder is carried out autonomously. This increases the efficiency of the compressor and reduces the reduced costs of producing compressed gas.

Claims (7)

1. A piston compressor comprising a crankcase, a cylinder with a piston disposed therein with a drive mechanism to form a working volume, a suction cavity connected to a gas source and with a working volume through a suction valve, and a discharge cavity connected to a gas consumer and with a working volume through a pressure valve, and around the working volume there is a liquid cooling jacket connected to a source of cooling liquid, characterized in that the lower part of the liquid cooling jacket is connected to a source of cooling azhdayuschey liquid and the top of the cooling jacket is connected with a cavity injection channel. 2. The piston compressor according to claim 1, characterized in that the coolant source is made in the form of an additional annular jacket, which is connected to the bottom of the cooling jacket by a channel (or channels) as a communicating tight vessel and has cooling fins on its surface. 3. A piston compressor according to claim 1, characterized in that a float having the form of a flat ring is installed in the upper part of the cooling jacket with a small radial clearance relative to its outer and inner diameters. 4. The piston compressor according to paragraphs. 1 and 2, characterized in that the lower part of the liquid cooling jacket is connected to the annular jacket using at least two channels, each of which has at least one sleeve in the form of a truncated cone, and in one channel the sleeve set apex towards the cooling jacket, and in another - apex towards the source of the liquid. 5. The piston compressor according to claim 1, characterized in that the channel connecting the discharge cavity to the upper part of the jacket has an inlet on the side of this cavity located directly above the discharge valve, in the form of a truncated cone, with a large base directed towards this valve . 6. The piston compressor according to claim 1, characterized in that the coolant source is made in the form of a container partially filled with liquid, which is connected through a non-return valve and a heat exchanger to the buffer cavity, which is connected through the non-return valve to the upper part of the cooling jacket, and a discharge cavity is connected to the upper part of the cooling jacket through said buffer cavity and a check valve. 7. The piston compressor according to paragraphs. 1 and 6, characterized in that the cooling jacket has a spiral protrusion along the axis of the jacket.

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