RU59163U1 - PNEUMATIC DEVICE FOR REGULATED GAS MEDIA SUPPLY TO OBJECT OF CONSUMPTION - Google Patents

Abstract

(57) Field of technology: compression systems for supplying gas from a source with constant parameters of pressure and gas flow to a consumer with a constant pressure parameter and variable parameters of gas flow. The essence of the utility model: the device contains a gas source 1 with constant pressure and flow parameters, connected to the discharge pipe 2, the output of which is connected to the jet compressor 4, connected through the discharge pipe 6 to the pressure regulator after itself 8 with the consumer 7 with a constant pressure parameter and variables gas flow parameters. The compressor passive flow pipe 4 is connected to a suction pipe 14 connected to a receiver 15, which is connected through a branch line 17 with a pressure regulator 18 to itself with a discharge line 2. If the consumer gas flow exceeds the source gas flow while ensuring their pressure is constant, reduction of the final pressure of the accumulated gas in the receiver to a value below the consumer pressure due to the suction of gas from the receiver through the passive stream pipe of the jet compressor 4, entirely COROLLARY which uses a smaller volume of the receiver. Achievable technical result: reducing the cost of the device. 1 s.p. f-ly, 3 s.p. f-ly.

Description

The utility model relates to the field of pneumatic automation, namely to compression systems for supplying a gaseous medium with constant parameters of pressure and gas flow, for example, oxygen or nitrogen to an object of consumption with a constant pressure parameter and variable flow parameters, and can be used in various fields of technology in a wide range of changes in its consumption by the consumer to create an inert gas environment used in the chemical industry to prevent fires and explosions, in metallurgy during the supply of acid Loroda as an oxidizing agent in the process of melting metals, ores, etc. in various types of furnaces, etc.

An analysis of the technical level in this field showed that a pneumatic device is known that contains a gas source connected to the inlet end of the discharge pipeline, a receiver, a pressure regulator to itself, a pressure regulator after itself, a branch line connected at one end to the discharge line, and the other end to receiver (Japanese Patent No. 3550931 B2 10228320A, IPC: G 05D 7/00, publ. 04/08/2004).

The inability to achieve the result provided by the claimed device is due to the fact that the device is designed to stabilize the gas flow and is not functional if you want to provide gas to the consumer with a variable gas flow, and, in addition, it uses a receiver of significant size, which leads to significant device cost.

Known pneumatic device for supplying a gas medium to a consumer, containing a gas source connected to the inlet end of the discharge pipe, the output end of which is connected to the inlet of the jet apparatus, connected by an outlet pipe to the inlet of the outlet pipe, the output of which is connected to the consumer, a regulator, and connected to one end of the suction pipe, the other end of which is connected to the passive flow pipe of the compressor unit she (RF Patent №1049868 A, IPC: G 05 D 7/00, publ 23.10.83 city.).

The impossibility of achieving a technical result provided by the claimed device is caused by the lack of the possibility in the design of an analog of regulating the gas flow rate in the range of its supply to the consumer while ensuring the constancy of its pressure both at the consumer and at the source, as well as the constancy of the flow of the gas source.

Of the known devices, the closest to the claimed one is a pneumatic gas supply device containing a gas source with constant flow and pressure parameters, connected to the inlet end of the discharge pipe, at least one receiver with a safety regulator, a pressure regulator before itself and a pressure regulator after itself, mounted on a by-pass pipeline connected with its outlet to the consumer with constant pressure and variable flow (electronic information via the Internet, Yandex, http: // ww w.cryoservice.ru/main.php?lang=rus&part=expl1, publ. 07/03/2006).

The inability to achieve the claimed technical result by the specified device is due to the fact that in the prototype when performing one of its work cycles, in which the gas is supplied to the consumer, the flow rate of which exceeds the flow rate of the gas source

while ensuring the constancy of their pressure values, it is necessary to pump the missing gas flow to the consumer either additionally from the source, or use a large volume receiver, provided that the pressure in the receiver approaches the consumer pressure. The above disadvantages lead to a significant price of the device, especially with multiple receivers

When developing the claimed design of a pneumatic device, the task was to reduce its cost.

In solving the aforementioned problem, a technical result was achieved, consisting in the development of a design into which an inkjet apparatus was introduced, which allows the consumer to exceed the gas flow rate of the source without exceeding the gas consumption of the source, without increasing the duration of the work cycle, which depends on the difference in the consumption of the consumer and the gas source receiver and the difference between the initial and final pressure inside the receiver, to reduce the overall dimensions of the receiver by reducing the pressure inside it below the consumer pressure by providing additional suction of gas from it.

The essence of the claimed technical solution lies in the fact that the pneumatic device for controlled supply of a gas medium to the consumer, contains a gas source of constant flow and pressure parameters connected to the inlet end of the discharge pipe, at least one receiver with a safety regulator, a pressure regulator to itself and a regulator pressure after itself, installed on a branch pipe connected by its outlet to the consumption object with constant pressure and variable flow rate.

New in the device is that an inkjet apparatus is introduced into it, the inlet pipe of which is connected to the output end of the discharge pipe, the output pipe is connected to the inlet of the discharge pipe, and the passive pipe is connected to one end of the suction pipe

a pipeline, the other end of which is in communication with a receiver connected through a branch line to a discharge pipe, the pressure regulator being installed on the branch line.

In addition, the gas source can be made in the form of an air separation unit, the jet device can be made in the form of a jet compressor, and pressure regulators before and after themselves can be made in the form of valves containing bellows assemblies with a spring interacting by means of a pusher with a shut-off valve .

The device is presented in the drawings, which depict:

Figure 1 - General diagram of a device with one receiver;

Figure 2 - General diagram of a device with multiple receivers;

Figure 3 - design of a pressure regulator to itself;

Figure 4 - design of the pressure regulator after itself;

The pneumatic device for the controlled supply of a gas medium to the consumer object contains a gas source made in the form of an air separation unit (ASU) 1 with air separation channels (not shown in the drawing), for passing separately, for example, oxygen or nitrogen, with constant pressure parameters P ₁ for example, 35 atm (or kg / cm ² ) and gas flow rate, for example, per hour 40,000 nm ³ (m ³ × atm or m ³ × kg / cm ² ). The output of the ASU 1 is connected to the input end of the discharge pipe 2, the output end of which is connected to the input pipe 3 of the jet apparatus, made, for example, in the form of a jet compressor 4, the output pipe 5 of which is connected to the input of the discharge pipe 6, connected to the consumption object 7 with a constant pressure P ₂ lower than in the source gas, e.g., 17 atm and a variable gas flow rate, e.g., 20,000 to 60,000 nm ³ / hr, as which may be used in a blast furnace in which oxygen is supplied from an oil tank or product storage tanks, which are supplied with nitrogen, etc. On the branch pipe 6, a pressure regulator is installed after itself 8,

made, for example, in the form of a valve (Figure 4) containing a bellows assembly comprising a spring 9 mounted on a membrane 10, interacting by means of a pusher 11 with a shut-off valve 12 with a spring, with the possibility of blocking the regulator through hole.

The pipe of the passive gas stream 13 (Fig. 1) of the jet compressor 4 is connected to one end of the suction pipe 14, the other end of which is connected to an air collector made in the form of a receiver 15 with a chamber inside it, designed to accumulate gas in the mode when the consumer takes less gas than the source produces it, and the return of gas if the consumer takes more gas than the source produces. The device may contain at least one receiver (Figure 1), or several receivers (Figure 2).

At least one safety regulator 16 is installed on the receiver to relieve pressure from the receiver's chamber when its permissible value is exceeded. In the device, a branch line 17 is mounted in the form of a pipeline, the input of which is connected to the discharge pipe 2, and the output to the receiver 15. A pressure regulator 18 is located on the branch line 17 (Figure 3), the design of which is similar to the design of the pressure regulator after itself 8, only the shutoff valve 12 is located on the other side of the passage opening.

The volume or flow rate of gas that the receiver can produce is:

where: Rn is the initial pressure in the receiver to which the gas source fills the receiver when the gas consumption is less than the capacity of the source, kg / cm;

Pk - the final pressure in the receiver, at a time when the gas consumption by the consumer is greater than the capacity of the source kg / cm ² ;

V is the excess consumption or volume of consumer gas over the source capacity (m ³ × kg / cm ² ).

For example. The compressor station delivers gas to the receiver with a constant pressure of 35 atm (kg / cm ² ) and a flow rate of 40,000 nm ³ per hour, while it is specified that the pressure at the consumer is also a constant value, for example, 17 atm (kg / cm ² ), and gas flow rate ranges from the initial value of 20,000 to the final 60,000 nm ³ (m ³ · kg / cm ² ). In this case, a change in flow from the initial minimum to the final maximum occurs within 1 hour.

The average excess of consumer consumption over source capacity is per hour or within half an hour -

The receiver volume then amounts to:

It follows that it is possible to reduce the volume of the receiver, and therefore its overall dimensions, while maintaining the specified parameters by reducing the value of the final pressure Pk in the receiver lower than that of the consumer. At the same time, the pressure P ₂ remains constant at the consumer. This can be achieved by compressing the gas taken from the receiver to a pressure of 17 atm, which is ensured by the introduction of a jet compressor, where the source gas is used as the active gas. The proposed installation allows to reduce it, for example, to 9-10 atm., Which reduces the volume of the receiver to 200 m ³ i.e. almost 30%.

The device operates as follows.

Compressed gas from source 1 with a constant flow rate and pressure enters through a pressure regulator 17 to itself, which maintains a constant gas flow from the source, to the receiver and through the working nozzle of the jet compressor 4 and also a pressure regulator after itself 8 to the consumption object 7 with a constant pressure parameter, but with a variable gas flow in a given range. Gas flow rate through the working nozzle

compressor 4 varies from 0 at a pressure P ₃ in the receiver equal to P _{1 of} source 1 to the maximum when the ratio of P ₃ to P ₂ becomes critical.

The operation of the device consists of three cycles.

When the first cycle is carried out, the gas consumption is consumed by the consumer, for example, from 20,000 nm ³ / hr to a value less than the output of the switchgear 1, for example, equal to 40,000 nm ³ / hr while ensuring constant pressure values. In this case, the pressure regulator after itself 8 operates according to the generally accepted scheme in such a way as to ensure constant pressure at the consumer and to pass the required gas flow to it, for which a specific spring tension 9 is set with the adjusting screw, based on the consumer pressure, for example, 17 atm, which the pusher 11 acts on the shutoff valve 12, providing it with a certain position relative to the passage opening when gas enters from the outlet pipe 6 to 35 atm. In this case, the difference in the gas flow rate, which is not required by the consumer, enters the receiver first through the passive flow pipe 13 and the suction pipe 14, and then through the open pressure regulator to itself 17, which ensures gas outlet to the receiver 15 chamber, where it accumulates, changing the pressure inside it from 9-10 atm to a maximum pH value. Then the gas enters only through the regulator 18. The cycle ends when the pressure Рн in the receiver becomes equal to P ₁ .

In the second cycle, when the consumption of gas consumption by the consumer is equal to the flow rate of the source, i.e. 40,000 nm ³ / hr. Gas from a source with a pressure of 35 atm passes through the working nozzle of the jet compressor 4 and through the regulator after itself 8, which converts it to 17 atm, to the consumer, while the pressure regulator does not pass the medium to the receiver 17. The pressure in the receiver while remaining equal to P ₁ .

The third cycle takes place when the consumption of gas consumption by the consumer, greater than the productivity of the gas source equal to 40,000 n · m ³ / hour,

for example, up to 60,000 n · m ³ / h. In this case, all the gas from the source goes to the consumer, and its missing value is taken from the receiver, reducing the pressure inside it. In this case, the pressure regulator to itself 18 is closed and the entire flow rate of the source enters through the nozzle 13 of the jet compressor. The pressure regulator after itself 8 provides a constant pressure at the consumer with a variable pressure in front of him. When the gas flow rate of the consumer 7 begins to exceed the flow rate of the source 1, the pressure in the receiver decreases to such a value (17-18 atm) that the regulator 8 cannot maintain the required pressure due to the lack of pressure drop across it. When the pressure in the receiver drops from 35 atm to a value close to 17 atm, the gas from the receiver enters through the pressure regulator after itself 8 to the consumer, while the pressure regulator 8 maintains the pressure of 17 atm at the consumer. As soon as the pressure in the receiver becomes close to P ₂ , i.e. at 17 atm the jet compressor 4 starts to work, which starts sucking gas from the receiver and at the same time mix this stream with the gas coming from the discharge pipe 2, while at the outlet of the jet compressor a mixed gas stream is formed with a pressure higher than the gas pressure in the passive nozzle of the jet apparatus. This is because when gas flows through the jet apparatus 4, gas is injected through the passive flow pipe from the receiver. Thus, when the receiver reaches a pressure close to P ₂ , the jet compressor 4 comes into operation, which additionally draws gas from the receiver and thereby creates the possibility for the regulator 8 to maintain the required pressure. As a result, the pressure Pk decreases, which can be significantly less than P ₂ , which allows the receiver volume to be reduced by an amount corresponding to the difference in these pressures.

The possibility of implementing the inventive pneumatic device is confirmed by the use of known elements and means, as well as non-deficient materials, existing and used in the field

pneumatic automation, for the implementation of this design, including the features presented at the level of functional generalization, with the achievement of a technical result, which consists in reducing the cost of the device by using receivers of a smaller volume, due to the fact that the device allows pumping gas from the receiver not only due to replenishing it from the source, as is done in the prototype, and which required significant volumes of receivers, but also to carry out additional pumping from them due to injection in the jet compressor, which allowed the use of receivers of smaller overall dimensions.

Claims (4)

1. A pneumatic device for the regulated supply of a gas medium to a consumer, containing a gas source with constant flow and pressure parameters, connected to the inlet end of the discharge pipe, at least one receiver with a safety regulator, a pressure regulator upstream and a pressure regulator installed on the outlet a pipeline connected by its outlet to a consumer with a constant pressure and variable flow rate, characterized in that a jet apparatus, a cat inlet pipe, is introduced into it It is connected to the outlet end of the discharge pipe, the outlet pipe is connected to the inlet of the discharge pipe, and the passive pipe is connected to one end of the suction pipe, the other end of which is connected to the receiver connected through the branch line to the discharge pipe, with the pressure regulator installed on the line branches. 2. The pneumatic device according to claim 1, characterized in that the gas source is made in the form of an air separation unit. 3. The pneumatic device according to claim 1, characterized in that the inkjet apparatus is made in the form of an inkjet compressor. 4. Pneumatic device according to any one of claims 1 to 3, characterized in that the pressure regulators before and after themselves are made in the form of valves containing bellows assemblies with a spring interacting by means of a pusher with a shut-off valve.