RU158066U1 - COMPRESSOR INSTALLATION - Google Patents

Abstract

A compressor installation comprising a compressor with an air filter, heat exchanger-utilizer installed on the discharge line, an end cooler, an air collector interconnected by main and additional pipelines, which are equipped with valves electrically connected to the control unit and temperature and pressure sensors, a pneumatic network, and the compressor equipped with a drive with a speed controller connected to the outputs of the temperature controller and pressure controller, and the temperature sensor and pressure sensor connected respectively to a temperature controller and a pressure controller, and the air collector is equipped with a vertically mounted swirl made in the form of four plates rigidly interconnected by an axis, the inlet and outlet sections of which are located at right angles to each other, in addition, the air collector in the lower part is equipped with a dirt collector characterized in that the inner surface of the air collector in its lower part in front of the dirt collector is coated with nanomaterial in the form of a glass-like film.

Description

IPC F04D 25/00

Compressor installation

 The utility model relates to the management of compressor units operated in climatic conditions with prolonged exposure to subzero temperatures, and especially for mining enterprises in the mining industry.

A known compressor installation (see RF patent No. 2281418, IPC F04D 25/00. Pub. 08/10/2006) containing a compressor with an air filter, heat exchanger-utilizer, end cooler, air collector connected to each other by main and additional pipelines installed on the discharge line which are equipped with valves electrically connected to the control unit and temperature and pressure sensors, a pneumatic network, while the compressor is equipped with an actuator with a speed controller connected to the outputs of the temperature controller and controller pressure, and the temperature sensor and pressure sensor are connected respectively to the temperature controller and pressure controller.

The disadvantage is energy costs due to the consumption of compressed air to remove condensed moisture from the pneumatic network as it moves to the consumer due to the lack of the possibility of intensive separation of finely divided condensed moisture in the air collector, which, when it is subsequently moved, burns energy-efficient pneumatic energy of the equipment. A known compressor installation (see RF patent No. 2535412, IPC F04D 25/00. Publ. 10.12.2014) containing a compressor with an air filter mounted on the discharge line heat exchanger-heat exchanger, end cooler, air collector, interconnected by main and additional pipelines which are equipped with valves electrically connected to the control unit and temperature and pressure sensors, a pneumatic network, while the compressor is equipped with an actuator with a speed controller connected to the outputs of the temperature controller and pressure, and the temperature sensor and pressure sensor are connected respectively to the temperature controller and pressure controller, while the air collector is equipped with a vertically mounted swirl made in the form of four plates rigidly interconnected by an axis, the input and output sections of which are located at right angles to each other, in addition, the air collector at the bottom is equipped with a dirt collector. The disadvantage is the energy intensity due to intensive destruction under the influence of external corrosion, especially the nipple in front of the dirt collector of the surface of the air collector and, accordingly, the presence of unscheduled repairs to replace the air collector.

The objective of the proposed utility model is to maintain the normalized life of the air collectors subjected to corrosive attack, especially in the lower part, where the inner surface is constantly in contact with the droplet-like moisture accumulated during storage and cooling by the air mixture before removal through the dirt collector, by raising it in the form of a glass-like film.

The technical result is achieved by the fact that a compressor installation comprising a compressor with an air filter, heat exchanger-heat exchanger installed on the discharge line, an end cooler, an air collector, interconnected by main and additional pipelines, which are equipped with valves electrically connected to the control unit and temperature and pressure sensors , a pneumatic network, while the compressor is equipped with a drive with a speed controller connected to the outputs of the temperature controller and pressure controller and the temperature sensor and pressure sensor are connected respectively to the temperature controller and pressure controller, and the air collector is equipped with a vertically mounted swirl made in the form of four plates rigidly connected to each other by an axis, the input and output sections of which are located at right angles to each other, in addition , the air collector in the lower part is equipped with a dirt collector, and the inner surface of the air collector in its lower part before the dirt collector is covered with nanomaterial in the form of fiberglass good film.

Figure 1 presents a schematic diagram of a compressor installation; figure 2 - air intake placed inside the swirl and the inner surface in the lower part coated with nanomaterial in the form of a glass-like film; in FIG. 3 - swirl made in the form of four rigidly connected to the axis and rotated plates.

The compressor installation consists of a compressor 1 installed on the discharge line 2 through the main pipe 3 and the valve 4 of the end cooler 5 and the air collector 6, the latter through the valve 7 is connected to the pneumatic network 8. The heat exchanger-utilizer 9 with an additional pipe 10 and valve 11 is connected to the discharge line 2, and an additional pipe 12 and a valve 13 is connected to the end cooler 5, in addition, the heat exchanger-utilizer 9 with an additional pipe 14 and a valve 15 is connected to the air collector 6, and an additional pipe 16 and valve 17 is connected to the pneumatic network 8. The control unit 18 is electrically connected to a temperature sensor 19 installed on the suction pipe 20 of the air filter 21, and a pressure sensor 22 installed on the pneumatic network 8. The actuator 23 is connected to the compressor 1 via a speed controller rotation, for example, in the form of a block of powder electromagnetic couplings 24. The temperature sensor 19 of the intake air is connected to the temperature controller 25, and the pressure sensor 22 of the compressed air in the pneumatic network 8 is connected to the controller 26. The pressure regulators 25 and 26, respectively, the temperature and pressure are in circuit-design solution and 27 comprise blocks 28 and comparison, respectively, which are connected to sensors 19 and 22, temperature and pressure, as well as blocks 29 and 30 tasks. The outputs of the comparison units 27 and 28 are connected to the inputs of the electronic amplifiers 31 and 32, equipped with units 33 and 34 of a non-linear reverse network. The outputs of the amplifiers 31 and 32 are connected to the inputs of the magnetic amplifiers 35 and 36 with rectifiers at the outputs that are connected to the electromagnetic clutch 24 of the drive 23 of the compressor 1. Inside the air collector 6 between the output 37 of the terminal cooler 5 and the valve 7 of the pneumatic network 8 is located a swirl 38, which is installed on height with vertical placement of the air bag 6. The swirl 38 is made in the form of four 39, 40, 41, 42 plates rigidly interconnected by an axis 43. The inlet sections 44, 45, 46, 47 of the plates 39, 40, 41, 42 are located at right angles regarding you -period portions 48, 49, 50, 51. Air collector 6 the lower portion 52 is provided with a dirt collection container 53 or the steam trap.

 The inner surface 54 of the air collector 6 in its lower part 52 in front of the dirt collector 53 is coated with nanomaterial 55 in the form of a glass-like film.

The compressor installation operates as follows.

Compressed air from outlet 37 after the end cooler 5, saturated with finely divided droplet-like and vaporous moisture, enters the air collector 6, where it is cooled under the influence of the ambient temperature (atmospheric air), and the vaporous moisture condenses, coarsening the finely dispersed particles of water and, in the presence of piston compressor 1, oil. The compressed air entering the air collector 6, in contact with the plates 39, 40, 41, 42, rigidly fixed on the axis 43, is divided by the inlet sections 44, 45, 46, 47 of the swirl 38 into four flows and moving to the outlet sections 48, 49, 50 51, turned 90 degrees, swirls, forming a vortex flow (see, for example, Merkulov VP The vortex effect and its application in industry. Samara 1991 - 298 p., Ill.) Under the action of centrifugal forces, condensed and coarse fine moisture particles (water and oil) are thrown to the inner surface of the air collection 6, flows into the lower portion 52 and collected in the dirt collection container 53, where either manually or automatically released into the environment.

 As the condensed and coarsened moisture moves, it adheres to the inner surface 54 and, especially, to the lower part 52 and together with the compressed air, the corrosive effect on the material of the air bag 6 is intensively carried out. As a result of the corrosion damage, unscheduled repair of the air bag 6 with everything that generally increases its operation.

To eliminate the process of corrosion damage, the inner surface 54 of the air collector 6 in the lower part 52 in front of the dirt collector 53 is coated with nanomaterial 55 and droplet moisture without the inner surface 54 in the dirt collector 53 is based on a glass-like film (see, for example, Kish L. Kinetics of electrochemical dissolution of metals. M .: Mir, 1990 - 276 p., Sludge) for further disposal into the environment.

Compressed air, purified from condensed moisture in the air collector 6 by means of a swirl 38 removed in the dirt collector 53, enters through the valve 7 into the pneumatic network 8. As a result, along the length of the pneumatic network 8 and in front of consumers of compressed air, due to the absence of finely divided droplet and condensing moisture, no the need to install condensate removal devices, which are mainly released into the environment by purging the pneumatic network element or moisture removal device, i.e. with a certain additional consumption of compressed air, which leads to an increase in the energy consumption of the compressor unit. Consequently, the presence of a swirl 38 in the air collector 6 ensures the collection and subsequent removal of condensed and finely dispersed moisture from the compressed air as it is cooled by the environment (atmospheric air) without additional energy costs associated with the subsequent consumption of compressed air for purging the elements of the pneumatic systems (pneumatic network and pneumatic equipment) . This ultimately reduces the energy consumption of compressed air production. At positive temperatures, when the intake air has a temperature close to normalized, the temperature sensor 19 mounted on the suction pipe 20 supplies a corresponding signal to the temperature controller 25, which is connected through the output of the magnetic amplifier 35 to the electromagnetic coupling 24 of the drive 23 of the compressor 1. As a result, under standardized operating conditions of the compressor installation (normalized compressor capacity and, accordingly, normalized drive rotation speed, divided by the positive normalized temperature of the intake air, see, for example, Reciprocating Compressors. Theory, Design and Design Basics / Frenkel MI - M.: Mechanical Engineering. 1969. - 774 p.) the signal from the magnetic amplifier 35 is fed to the winding of the electromagnetic clutch 24 with a value for the speed of rotation of the actuator 23, guaranteeing normalized compressor performance. In this case, atmospheric air enters the air filter 21, where it is processed to the specified parameters for cleaning from contamination in the form of solid particles of droplet and vapor moisture and through the suction pipe 20 enters the compressor 1, where it is compressed. During the air compression process, the control unit 18 closes the valves 11, 13, 15 and 17, and opens the valves 4 and 7. After compression, air with a temperature of over 120 degrees is sent via discharge line 2, the main pipeline 3 and through valve 4 enters the terminal cooler 5, where it is cooled to a temperature of about 100 degrees. Next, the cooling process of compressed air continues in the air collector 6, where the condensation of moisture vapor in the compressed air takes place. From the air intake 6 through the open valve 7, compressed air with a temperature exceeding the ambient temperature by 20-40 degrees. enters the pipeline 8 of the pneumatic network. As a result, thermal equilibrium does not occur along the length of the pneumatic network 8, i.e. equal temperature of compressed air and the environment. As a result, condensation of the remaining moisture vapor practically does not occur, and compressed air with a given pressure, detected by pressure sensor 22, enters the consumer's pneumatic network.

A change in the number of consumers simultaneously using the compressed air produced by the compressor unit (working breaks, change hours, and other reasons) and connected to the pneumatic network 8 leads to pressure fluctuations in it, which is detected by the pressure sensor 22 connected to the pressure regulator 26. When a certain decrease in the flow rate of compressed air and, accordingly, an increase in the pressure of the pneumatic network 8, the signal coming from the pressure sensor 22 exceeds the normalized signal of the task unit 30, and the signal al negative polarity supplied to the input of the electronic amplifier 32 simultaneously with a negative feedback signal (block 34). Due to this, the non-linearity of the characteristics of the drive 23 of the compressor 1 is compensated in the amplifier 32. The signal from the output of the electronic amplifier 32 is fed to the input of the magnetic amplifier 36, where it is amplified by power, rectified and fed to the winding of the electromagnetic clutch 24 of the compressor 1. The negative polarity of the signal of the electronic amplifier 32 causes a decrease in the excitation current at the output of the magnetic amplifier 36, thereby reducing the moment transmitted by the clutch 24 from the drive 23. This reduces the speed of the compressor 1 and the air supply ha compression decreases as long as the pressure of the pneumatic 8 will not be given.

With a slight increase in the flow of compressed air in the pneumatic network 8 and a corresponding decrease in pressure in it (the simultaneous inclusion of a significant number of consumers of compressed air connected to the pneumatic network 8), the signal of the task unit 30 will exceed the signal of the pressure sensor 22, and a positive signal appears at the output of the comparison unit 28 polarity, which, passing through the electronic amplifier 32, increases the excitation current at the output of the magnetic amplifier 36, thereby achieving an increase in air supply by the compressor 1 to those p until the pressure in the pipeline 8, becomes equal to the specified value.

At minus ambient temperatures, when the density of intake air increases and, accordingly, lower mass productivity of compressor 1 is required (see, for example, Kurchavin V.M. Saving thermal and electric energy in reciprocating compressors. - M .: 1985. - 80 s .) to maintain the normalized parameters of compressed air in the pneumatic network 8, it is necessary to switch to a lower temperature level for intake air. In this case, the signal from the temperature sensor 19 becomes larger than the signal of the reference unit 29, and a negative polarity signal appears at the output of the comparison unit 27, which is input to the electronic amplifier 31 simultaneously with the negative feedback signal (block 33). Due to this, the non-linearity of the characteristics of the drive 23 of the compressor 1 is compensated in the amplifier 31. The signal from the output of the electronic amplifier 31 is fed to the input of the magnetic amplifier 35, where it is amplified by power, rectified and fed to the winding of the electromagnetic clutch 24 of the compressor 1. The negative polarity of the signal of the electronic amplifier 31 causes a decrease in the excitation current at the output of the magnetic amplifier 35, thereby reducing the moment transmitted from the clutch 24 from the drive 23. This reduces the speed of the compressor 1 and the supply of compress of the air reaches values specified for normalized consumers pneumatic 8.

In this case, the aspirated atmospheric air saturated with solid particles of liquid in the form of snow, hoarfrost and / or drop-like moisture enters the air filter 21, where it is cleaned, and is sent through the suction pipe 20 to the compressor 1 for compression. Through the discharge pipe 3 through an open valve 4 enters with a temperature of about 120 degrees in the end cooler 5 for partial cooling of the air bag 6.

In the air collector 6, the process of condensation of moisture vapor not separated in the air filter 21 is carried out. Compressed air with a temperature 10-20 degrees higher than the ambient temperature through the open valve 7 enters the pneumatic network 8. As a result of exposure to the pneumatic network 8 of the environment with subzero temperatures intensive cooling of the compressed air with condensation of moisture vapor is carried out, and the liquid that has appeared in the pipeline, freezes when it cools. This leads to a sharp increase in the hydraulic resistance of the pipelines of the pneumatic network 8. In this case, along with a change in the temperature of the compressed air, its pressure also changes, which is detected by the pressure sensor 22, from which the signal enters the control unit 18.

As a result of the action of the control unit 118 on the electrically connected valves, the following operations are carried out: valves 11, 13, 15 and 17 are opened, valves 4 and 7 are closed. Then, compressed air from compressor 1 with a temperature of about 120 deg. through the open valve 11 through the auxiliary pipe 10 enters the heat exchanger-utilizer 9, where it gives off part of the heat, and through the auxiliary pipe 12 through the open valve 13 is sent to the end cooler 5. Joint cooling in the heat exchanger-utilizer 9 and in the air collector 6 provides an additional temperature reduction compressed air to values close to ambient temperature, i.e. in the air collector 6, almost complete condensation of moisture vapor is carried out. From the air collector 6, compressed air through an additional pipe 14 through the valve 15 enters the heat exchanger-utilizer 9, where it is heated to 10-20 degrees. (heat is taken from the flow of compressed air moving directly from the compressor 1) and through an additional pipe 16 through the valve 17 is sent to the pneumatic network 8.

The arrival of heated air to the ground pneumatic network 8 with a reduced amount of vaporous moisture provides a flow without cooling to ambient temperature and, accordingly, without condensation falling along the length of the pneumatic network. As a result, compressed air of a predetermined normalized pressure enters the pneumatic network 8, which is detected by a pressure sensor 22 obtained with lower energy consumption due to lower rotational speeds of the drive 23 of compressor 1, because air entering it has a higher density due to subzero ambient temperatures.

When changing the operating mode of consumers of compressed air connected to the pneumatic network 8, the pressure in it fluctuates both in the direction of decrease and in the direction of increase, which is detected by the pressure sensor 22. In this case, the procedure for maintaining the normalized parameters of compressed air in the pneumatic network 8 is carried out in the same way as in the production of compressed air at positive ambient temperatures (described above), but at a lower energy intensity level of operation of the actuator 23, acting through a speed controller, for example, in the form of a block of powder couplings 24 to the compressor 1.

The originality of the proposed utility model lies in the fact that coating the inner surface of the air collector, especially in the lower part with nanomaterial in the form of a glass-like film, eliminates the corrosive effect on the material of the air collector. As a result, the compressor unit is operated without unscheduled repairs related to the replacement of air collectors that are destroyed by corrosion, and this ultimately reduces the electric capacity.

Claims (1)

A compressor installation comprising a compressor with an air filter, heat exchanger-utilizer installed on the discharge line, an end cooler, an air collector interconnected by main and additional pipelines, which are equipped with valves electrically connected to the control unit and temperature and pressure sensors, a pneumatic network, and the compressor equipped with a drive with a speed controller connected to the outputs of the temperature controller and pressure controller, and the temperature sensor and pressure sensor connected respectively to a temperature controller and a pressure controller, and the air collector is equipped with a vertically mounted swirl made in the form of four plates rigidly interconnected by an axis, the inlet and outlet sections of which are located at right angles to each other, in addition, the air collector in the lower part is equipped with a dirt collector characterized in that the inner surface of the air collector in its lower part before the dirt collector is coated with nanomaterial in the form of a glass-like film.

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