FI103739B - Procedure for preventing clogging of a filter - Google Patents

Description

103739

Method for preventing filter clogging - Förfarande för förhindrande av tilltäppning av ett filter

BRIEF DESCRIPTION OF THE INVENTION The present invention is directed to a method of preventing ice and / or frost formation in a compressor air filter by passing cold air through this filter to the compressor. This method employs radiation to prevent the formation of ice and / or frost on the filter.

BACKGROUND OF THE INVENTION Clean and filtered air is required in industry for various processes such as nitric acid, air distillation and gas turbine plants.

When industrial air is filtered with cold air, the moisture in the air crystallizes into ice or frost on the filter surface and clogs the filter, thereby preventing air flow and increasing the flow resistance of the filter. Particularly in the industry where centrifugal compressors are used to produce compressed air, the obstruction of the suction filter, for example due to freezing, causes the compressor to run seriously. For other types of machines, such as piston and screw compressors, clogging of the suction filter causes additional heating and consequent malfunctions.

There is an air filter on the suction side of the compressor to ensure clean air. Centrifugal compressors have a specific operating constant, specific to each compressor, to the pressure ratio and pumping limit within which the compressor must operate.

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The pressure ratio is the absolute pressure divided by the absolute pressure side of the suction ·;. ·. pressure. If the suction filter is blocked or frozen or white frost is formed, the suction • · · the pressure decreases relatively quickly and the pressure ratio increases according to the following formula .. 25 kaisesti: · • • ♦ ♦ pressure-side pressure (abs) - = the pressure ratio.

':: suction pressure (abs)

As the pressure ratio rises above the pumping limit, the compressor's ability to raise '· "30 pressures rapidly deteriorates and the compressed air on the compressor pressure side is discharged back through the compressor. This results in an increase in pressure in the suction line, lowering the pressure ratio A situation arises when the air flow through the compressor changes back and forth, reversing very quickly, causing the compressor to enter the pumping state, which causes major changes in the air flow and power requirements that are dangerous not only to the compressor itself, causing 5 disturbances in the process itself.

To prevent the suction filter from freezing, the compressor manufacturers have set the minimum suction air temperature to the filter before the filter at +2 to + 5 ° C, and in practice the suction air is kept at about + 5 ° C for safety reasons.

It is generally known that the freezing of the filter is prevented by preheating the air to be filtered to +2 to + 5 ° C, e.g.

When preheated air is supplied to the suction filter in an industrial hall, impurities in the air, such as various gases or solid particles, may cause problems with the compressor or process. Particularly in the chemical industry, chemical compounds can be formed that dirt the compressor and process equipment, e.g. small amounts of nitric oxides and ammonia in the indoor air are present in the nitric acid plant, which can form various ammonium salts.

The ammonium salts formed, in addition to clogging the suction filter and the consequent increasing pressure drop and further energy loss, also increase the need for washing process equipment. For washing, the factory must be stopped, whereby:: the capacity of the factory is reduced.

• · * · # "All known methods described above consume relatively large amounts of energy. In particular, when the intake air is heated by drawing in the compressed air from the compressor pressure side, at the same time the compressor capacity is reduced.

• · *

The above technique has been applied e.g. for preventing the freezing of an airplane gas turbine (U.S. Patent 4,831,819).

I · I · 30 Heating the intake air in a separate heating system with fuel requires not only energy, but also separate equipment, which in turn can cause '·': interference with the compressor and process. This technique has been applied e.g.

3,103,739 in a method according to U.S. Patent 4,328,666 for preventing filter freezing.

It is generally known that radiation can be used for heating and de-icing. U.S. Patent No. 5,134,266 describes a method for melting ice from solid surfaces, such as an airplane, rocket, etc., by applying radiation-heated air to an icy surface.

JP Patent Publication 8193435, in turn, discloses an IR thermal radiator that can be used in buildings, streets, railways, etc. for defrosting ice and preventing ice formation. Ko. the wavelength emitted by the thermal radiator of the invention is 10 to 25 micrometers.

Further, U.S. Patent No. 5,417,389 discloses an infrared emitting device and method for defrosting ice from an airplane surface.

DISCLOSURE OF THE INVENTION This invention relates to a method of preventing ice and / or frost formation on an air filter and possibly other surfaces of a compressor by passing cold air through said filter to increase the capacity of the compressor, wherein the air and / or filter surface is exposed to radiation and to prevent frost formation, which radiation does not substantially increase the temperature of the air supplied to the compressor.

Thus, the method according to the invention allows the introduction of cold air without preheating it through the filter to the compressor without ice and / or frost forming on the filter. The use of cold air in the compressor is advantageous, ♦ i * ·· because it allows the compressor to be increased in capacity. According to the invention: *: ': an increase in the capacity of the compressor is obtained which is substantially directly proportional to the decrease in the temperature of the air supplied to the compressor.

The temperature of the air supplied to the compressor according to the invention is 0 ° C or less: 0 ° C.

In the method according to the invention, radiation having a wavelength of; in the range 800 nm to 300 mm.

. . : 30 The radiation may be, for example, infrared radiation or microwave radiation. According to the invention it is also possible to use different combinations of radiators, such as infrared radiators and microwave radiators.

4, 103739

In the method according to the invention, radiation, especially infrared and / or microwave radiation, is applied to the intake air before and / or on the filter surface. The effect of radiation directed at the intake air is specifically directed at the humidity in the air, water molecules or other polarizable compounds. Without gas mole-5, the radiation is not affected. The radiation increases the amount of thermal energy in the water particles in the air, so that they are farther away from the crystallization space and leave to freeze up to the compressor. When using this method, the radiation does not substantially increase the air temperature and the amount of operating energy required by the method is small. The temperature rise is preferably about 1-2 ° C. However, it is to be understood that, for example, air humidity and other factors may influence the temperature rise, so that the temperature rise may deviate from the above preferred range.

The amount of air supplied to the suction filter and other conditions will determine the power demand, quantity and quality of the radiators and their installation, such as distance from the filter and downstream or upstream of the airflow.

15 All radiators must be designed, installed and used in such a way that they do not endanger persons or materials.

The radiators are positioned so that the radiation meets the compressor's air evenly and the residence time is sufficient.

Particularly in the placement of microwave radiators, it should be noted that the irradiation field 20 is free of unsuitable materials and that electromagnetic interference radiation is prevented.

The invention will now be described in more detail with reference to the accompanying drawings, in which: Figure 1 schematically illustrates a system employing the process of the invention, and Figure 2 shows the capacity of a compressor as a function of temperature.

The method according to the invention has been applied at Kemira Agro Oy's Siilinjärvi nitric acid plant (Figure 1). Ko. at the factory, compressor 1 sucks air through about 50,000 m 2 / h ♦ · · 'suction filter 2 and compresses it to process 3 to about 4 bar.

The size of the inlet port of the suction filter 2 in this process is about 3 m x 2.5 m, i.e. about 7.5 m 2.

; In the method of the present invention, four pieces of infrared radiators 4 are mounted in the suction duct before the suction filter, which are directed downstream of the 103739 air flow and located about 1 meter from the filter. The electric power absorbed by each radiator is 2 kW, or a total of 8 kW.

In the past, known techniques were used to prevent the suction filter from freezing and frost formation, warming the freezing air to + 5 ° C with a hot water radiator 5, and removing warm air from inside the factory hall. In the process of the present invention, air is supplied to the compressor at a temperature of -20 ° C through a suction filter. With this method, it is possible to supply cooler air to the suction filter and the compressor, at the factory, the cold resistance of the suction line sets the limit to -20 ° C.

10 Figure 2 shows the practical measurement results of the present invention. an increase in the capacity of the compressor of a nitric acid plant when air having a temperature below 0 ° C may be introduced into the compressor. Figure 2 shows that if the compressor suction temperature is about + 5 ° C, which is a prior art practice, the compressor has a capacity of about 51,000 Nm 2 / hr.

The present invention has been able to introduce air into the compressor at a temperature of -20 ° C and a compressor capacity corresponding to that temperature of about 58,500 Nm 2 / h, i.e. an increase in capacity in the process. condition is 7,500 Nm ^ / h, or 14.7%.

Only one preferred embodiment of the invention has been described above and it is clear that it can be modified within the scope of the appended claims.

Thus, infrared radiators may be replaced by microwave radiators, or microwave radiators may be used in addition to infrared radiators. In the latter case, four radiation * · / · * ice, which mainly emit microwaves, can be conveniently installed in the suction duct before the infrared radiators. These microwave radiators can be mounted upstream of the airflow. The electric power of each microwave radiator can, for example, be 1 kW or 4 kW in total.

^ The Benefits of the Method The technique of the invention achieves a variety of advantages over the prior art; * to other prior art.

1 ·; The air flowing to the compressor does not need to be heated, which saves heating energy. 30 aa. This method only needs the operating energy of the radiators.

Since the air going to the compressor does not need to be heated, the capacity of the compressor firstly increases by increasing its density as the air cools down, and more compressed air fits into the compressor suction space. Second, the centrifugal compressor-Sor increases its capacity by the fact that the centrifugal force of cold and therefore heavy air is greater than that of warm and therefore lighter air.

With this technique, the power consumption of the compressor is reduced as calculated per pump per 5 m 2 of air. According to the compressor equations, the power requirement of the compressor is directly proportional to the absolute temperature.

On the other hand, the power requirement is reduced as per air produced or calculated per unit of plant product, so that the energy required for auxiliary and peripheral equipment is not increased as the compressor or plant capacity increases, but the py-10 cause is almost unchanged.

With this technique, clean outdoor air can be supplied to the compressor, thus avoiding the disadvantages caused by contaminated air preheated in the factory hall.

The equipment used in accordance with the present invention has a low purchase price, is easy to control by automation, has a high reliability, is freeze-free, easy to use and requires little maintenance.

Applying this technology will result in higher production per unit with the same operating and maintenance costs, since the increase in production obtained by this technology will not increase the production of the unit. costs.

By switching from the old technology to this technology, the capacity of the compressor and possibly of the factory unit can be increased with the lowest investment cost. -loss.

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Claims (6)

103739 A method for preventing the formation of ice and / or frost on the compressor air filter and possibly other surfaces by passing cold air through said filter to increase the compressor capacity, characterized in that the air and / or filter surface to be filtered is exposed to radiation and / or frost formation. , which radiation does not substantially increase the temperature of the air supplied to the compressor. 2. Förfarande enligt patentkrav I, rotation angle at temperature of 1-2 ° C. . y. 3. Förfarande enligt patentkrav 1 eller 2, tiltneck av att tempuren hos «· ....: 30 luften som leds compression at 0 ° C eller under 0 ° C. 103739 Method according to Claim 1, characterized in that the radiation raises the air temperature to about 1-2 ° C. Method according to claim 1 or 2, characterized in that the temperature of the air supplied to the compressor is 0 ° C or less than 0 ° C. 4. Förfarande enligt nägot av föregäende patentkrav, kännetecknat av att vg-längden hos stralningen är 800 nm - 300 mm. Method according to one of the preceding claims, characterized in that the radiation has a wavelength of 800 nm to 300 mm. 5. Förfarande enligt Face to face patent application, kännetecknat av att sträl-5 jaen infraröd strälning. Method according to one of the preceding claims, characterized in that the radiation is infrared radiation. Method according to one of Claims 1 to 4, characterized in that the radiation is microwave radiation. : '. 1. Föifarande för förhindrande av is- och / eller frostbildning pä ett luftfilter för en • ...; 20 Compressors och möjligen päandra ytor dä Kali luft leds genom nietra filter till \ 1. · Compressin i avsikt att höja compressor capacity, kännetecknat av att luften som skall filtereras och / eller filterytan utsätts for straining förhindrande av- , I am straining ej väsentligen Höjer temperaturesuren hos luften som leds account I compressed. ! · ·. 25 • · · 6. Förfarande enligt Face to face patent craven 1-4, kännetecknat av att strälningen är mikrovägssträlning. • «♦ ··» »• ♦ ♦ ♦ ♦ m m m 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1