SU1726116A1 - Unit for cooling an iron-casting conveyor machine - Google Patents

Abstract

The proposed device contains 5-11 mixing chambers, the length of which is adjustable with additional nozzles. The length of the mixing chambers is regulated by the law n, where is the n-order number of the chamber, and increases in the direction of water supply. A pipe with air inlets is placed on the body of the device. The design of the device will allow extending the range of regulation of the distribution of the cooler to the injectors in a wide range of flow rates of 0.7-3.0 m3 / h per injector for large flow areas, ensuring stable operation on the limestone circulating cycle water. The level of temperature fluctuations will decrease, the durability of the molds and the quality of the iron castings will increase. 1 hp f-crystals, 1 tab., 3 ill.

Description

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The invention relates to ferrous metallurgy and can be used on iron casting conveyor machines.

A known sprayer of a cooling system for continuous casting plants comprising a cylindrical hollow body with diffuser openings, provided with a cylindrical nozzle with nozzles mounted coaxially with the openings of the body.

The disadvantages of the design of this sprayer include the fact that with the horizontal arrangement of the sprayer, as is necessary in the iron casting machine, the cooler is unevenly distributed through the nozzles at low pressure of the water-air emulsion (0.2-0.5 atm). The transition to a higher pressure level due to a proportional decrease in the flow areas and outlet openings of the nozzles reduces the reliability of the operation of the sprayer when working on the water of the circulating cycle of the iron casting machine.

Of the known devices, the closest to the proposed technical entity is a device for cooling a continuously cast ingot, comprising a cylindrical body with cylindrical mixing chambers, a pipe with holes in it. In this case, each mixing chamber is fixed in the wall of the housing with the possibility of movement in the direction of its longitudinal axis.

The disadvantages of the design of this device include low reliability when working on the circulating water on the circulating cycle of the iron casting machine, as well as the narrow range of regulation of the required cooling technology for the nozzles with large ratios

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ABOUT

course of the cooler (more than 0.7 m3 / h at the nozzle).

The purpose of the invention is to increase the reliability of the device, increase the durability of the tars and improve the quality of the iron castings. The goal is achieved by the fact that a device for cooling an iron-casting conveyor machine comprising a cylindrical body with cylindrical mixing chambers having a means for adjusting their length, an air supply pipe with nozzles arranged coaxially with the mixing chambers, spray nozzles and nozzles for supplying water and air, equipped with composite mixing chambers with the ability to adjust their length by means of cylindrical nozzles. The length of the chambers is increased in the direction from the water inlet pipe to the air inlet pipe according to Vn, where p is the serial number of the chamber and the tube with air inlets is placed on the housing. The number of cameras in one device is set within 5-11.

Fig, 1 shows a device, a general view, a longitudinal section; Fig. 2 shows the distribution curves of water over the nozzles (curve 1 for the case of the same length of the mixing chambers, curve 2 for the case with the length of the mixing chambers changed according to the law YD); in FIG. 3, the dependences of the reliability factor of the device K (curve 1) and the uniformity of distribution of the cooler (curves 2-4) on the number of nozzles on one autonomous collector.

The device is made in the form of a collector and consists of a housing 1 on which a pipe 2 with nozzles 3 is fixed. The housing is equipped with a nozzle 4 for supplying a cooler, and a pipe 2 with a nozzle 5 for supplying compressed air. Mixing chambers 6 with additional cylindrical nozzles 7 and nozzles 8 are rigidly fixed in the housing.

The device works as follows.

Compressed air at a pressure of 1.5-4 atm through pipe 5 is fed into pipe 2 and through pipe 3 enters the mixing chambers 6. Water under pressure 0.5-2.0 atm through pipe 4 enters the housing 1 in the opposite direction the movement of compressed air in pipe 2, and further into the mixing chambers, partially by jets, partly in the form of a water-air flow, which is formed due to the ejection of water by air at the inlets to the mixing chambers.

The air-emulsion formed in the mixing chambers is sprayed at the outlet of the nozzles and, in the form of conjugate water-air flows, flows onto the surface of the castings and the molds. It was established experimentally that when the mixing chambers are elongated in the direction from the water supply nozzle to the air supply nozzle to the collector, the hydraulic

air resistance and reduced resistance to the passage of the cooler, which contributes to the redistribution of the cooler in an accelerated direction. With the same length of mixing chambers

The distribution of the cooler in the mixing chambers is essentially uneven (Fig. 2, curve 1). The extension of the mixing chambers from the first AND to the last ln allows to obtain a more uniform distribution of the cooler (Fig. 2, curve 2). In the first case, the uniformity of the distribution of the cooler Tr 0.07, in the second - c 0.6; uniformity is defined as f Gn / Gi, where Gi is the flow rate of the cooler on the first mixing chamber, Gn on the last one.

The distribution of the cooler in the mixing chambers (respectively, along the length of the conveyor) directly affects the level and uniformity of heat removal from the mold and

cast iron billet, and through these parameters to temperature fluctuations and therefore cracking in the trough and billet, i.e. on the durability of molds and the quality of cast iron billets. This is due to the fact that

the heat flux density q for air-borne sprayers non-linearly depends on the flow rate of the cooler:, where A is a coefficient whose value lies in the range 3-102-103, b 1. Maximum

the heat capacity at b1 is reached in the case of rj and decreases with decreasing f.

Thus, the elongation of the mixing chambers from the first I to the last allows, while maintaining the total flow rate of the cooler.

on the collector, to increase both the level of heat removal and the uniformity of heat removal from the workpiece and the mold, which provides an increase in durability of the molds and an improvement in the quality of the blanks.

The selection of the length And is carried out within 1-4 of the diameter of the nozzle outlet. A smaller value And sharply reduces the kinematic energy of the flow from the first nozzle, and a large one leads to an unacceptable increase in the vertical size of the device. Using a dependency that gives a less drastic increase in In (e.g., IrHiVn) only allows a 15-20% increase in the uniformity of distribution.

cooler. The use of a stronger dependence (for example,) dramatically increases the vertical size of the device, which, with increasing uniformity in the distribution of the cooler, leads to a decrease in the uniformity in the distribution of the kinetic energy of the flows flowing onto the multi- media conveyor. As a result, the uniformity of heat removal drops sharply, which leads to a decrease in the resistance of the molds and the quality of the blanks. The distribution of ln and P provides the best combination of the uniform distribution of the cooler and the kinetic energy of the streams in comparison with the indicated dependences.

Experiments have shown that placing a pipe with nozzles inside the case leads to the rapid formation of lime deposits on the protruding parts, which leads to a disturbance in the distribution of the cooler in the mixing chambers and a drop in the reliability of the device. The reliability of the device affects the durability of the molds and the quality of the workpieces due to the fact that when the machine fails (clogging up lime) of one or more nozzles of the device, non-irrigated zones are formed on the conveyor where the surface of the workpieces and their associated surface are heated. Along with this, there is a subcooling of blanks and molds in the irrigation zone of operating nozzles, to which the cooler is redistributed, which does not pass through the nozzles that have gone out of order. This leads to an increase in the amplitude of temperature fluctuations in the mold and the workpiece and, in accordance with one of the mechanisms of cracking, to an increase in cracking in the mold and the workpiece. The presence of cracks on the surface of the mold leads to sticking of the cast iron during pouring and loss of both the cast iron and the mold itself. The presence of cracks in the workpiece is a defect, since overloading this leads to a loss of metal.

Placing a pipe with connections outside the casing increases the reliability of the device, reduces the diameter of the cylindrical body and repairs the suitability of the device by eliminating protruding parts in the internal cavity of the device.

The implementation of composite mixing chambers makes it easy to change their length with changing technological cooling regimes associated with changing casting parameters (weight of workpieces, conveyor speed, water temperature)

and thus regulate the cooling process during the periods between castings.

The limitation of the number of nozzles (according to the mixing chambers) in the collector is limited by the requirements for reliable operation of individual collectors and the cooling system on the water, as a whole, and the thermal technology defined by the allowable degree of uneven distribution of the chiller along the conveyor length.

With the most common for an iron-casting machine, the length of the conveyor 40-43 m, the number of spray points N in the cooling system, providing a continuous water-air flow, is 60-90.

The table shows the options for arranging the cooling system from the collectors with different n (M is the number of collectors in the system).

As can be seen from the table, when assembling a cooling system from collectors with 13, the number of system modules (collectors) increases significantly when switching to collectors with four or less nozzles. This leads to both an increase in the cost of the system and a significant decrease in reliability, since each collector is equipped with at least two valves (for water and for air), as well as other shut-off and measuring fittings. The latter is illustrated in FIG. 3 by the course of curve 1, from which it can be seen that a decrease in the coefficient of reliability K, defined by the value of 1 / M, becomes significant when n 5 (the bend in curve 1).

It was established that with n 5 the diameter of the cross section of the water flow in the coolant supply pipes to the manifold becomes smaller than the diameter of the nozzles (mm). As a result, the air flow penetrates the water inlet and the shut-off and measuring fittings, disrupting its operation. It was determined that when d 25 mm there is a rapid overgrowing of the pipes with lime. For nozzles that can be periodically cleaned, the diameter of the outlet is greater than 10 mm. Thus, at point 5, both the reliability of operation of individual collectors with shut-off and measuring valves, and the reliability of the system as a whole when operating on limited water, decreases significantly and the cost of the system increases markedly.

Fig. 3 shows experimental curves 2-4, reflecting the uniform distribution of the cooler on

collectors with different p at the costs corresponding to the technology of casting iron on a conveyor machine (0.7-3.0 m / h per injector). As can be seen from the course of curves 2-4, the uniformity drops significantly with and for collectors equipped with nozzles with mm and mm c 0.5, which is unacceptable under the terms of the cooling technology. The same significant drop is observed for collectors from mm. It should be noted that the nozzles from mm overgrow 1.7-2 times faster than nozzles from 10 mm.

Thus, the experimental and calculated data on the reliability of the collectors and the cooling system, as well as the uniformity of the distribution of the cooler among the injectors, indicate a significant deterioration of these characteristics at 11 and 5. The choice of the option from the limits is determined by the specific requirements for reliability, cost, and thermophysical characteristics. iron casting machine cooling systems.

The proposed device ensures stable operation of the cast iron + jazz-casting machine on the water of the circulating cycle. By reducing the level of temperature fluctuations significantly

Note. The numbers in parentheses indicate excessive (+) or insufficient (-) number of spray points N in the system. In this case, a combination of collectors with different p.

The durability of the molds increases and the quality of the iron castings is improved.

Claims (2)

1. A device for cooling a casting iron conveyor machine, comprising a cylindrical body with cylindrical mixing chambers having means for adjusting their length, a pipe with air inlets arranged coaxially with the mixing chambers, spray nozzles and nozzles for supplying water and air that are different the fact that, in order to increase the reliability of the device, increase the durability of the tundas of the casting machine and improve the quality of the iron castings, the pipe with air inlets is placed on the core The mixing chambers are made composite with the possibility of adjusting their length by means of additional cylindrical nozzles, the length of the chambers increasing from the nozzle for supplying water to the nozzle for supplying air according to n, where n is the order number of the chamber. 2. The device of claim 1, wherein the number of cameras in one device is 5-11. g and s yu died injector, n Figure 2 tl V