RU48046U1 - GAS PIPE BUNCH HEAT EXCHANGE PIPES GAS AIR COOLING UNIT - Google Patents

Abstract

The utility model relates to the field of heat power engineering, namely to finned heat-exchange tubes and can be used in gas air coolers. The finned tube of the ABO gas heat exchange tube bundle contains the body of the heat exchange tube and external fins, which create in the transverse cooling stream of the external heat transfer medium aerodynamic shading sections of different intensities in a conventional plane normal to the vector of the mentioned external heat transfer medium flow and passing through the central longitudinal axis of the pipe: aerodynamic shading corresponding to the projection area on the specified plane of the unit length of the pipe body itself, excluding the fin incomplete aerodynamic shading, corresponding to the total projection area on the indicated plane of the finning sections per unit length of the finned tube, bounded on each side of the conditional straight line drawn along the tops of the ribs, minus the area of total aerodynamic shading created by the pipe body without taking into account finning according to the radius of the fins, the specific area of aerodynamic shading in the areas of projection of the fins on the specified plane per unit length of the pipe is 0.08-0.55. The technical result provided by this utility model consists in increasing the heat and aerodynamic characteristics of finned heat-exchange tubes and the thermal efficiency of the apparatus as a whole, as well as in reducing the metal consumption and the dimensions of the design of the bundle of heat-exchanging tubes for air-gas heat exchangers.

Description

The utility model relates to the field of heat power engineering, namely to finned heat-exchange tubes and can be used in gas air coolers.

Known bimetallic heat transfer pipe with seamless rolled aluminum fins in order to reduce thermal resistance, between the contacting surfaces of the pipe and fins placed a sleeve of ductile metal of lead, 200-260 microns thick, filling the voids formed during knurling (see SU 434252, F 28 F 1 / 24, F 28 F 21/08).

The closest analogue is a heat-exchange cylindrical element, with transverse ribs having a metal coating on the surface, in order to intensify heat transfer, the coating is made of a material with higher thermal conductivity than the material of the ribs and has a thickness that is variable in height of the ribs (SU 1416849, F 28 F 1/24, F 28 F 13/18).

A disadvantage of the known pipes is their insufficient thermal efficiency, as a result of which long pipes are required to be able to obtain a compact heat exchanger. For AVO gas, the optimization of the parameters of heat exchange elements, or more precisely finned tubes, is a difficult problem due to their large dimensions and large metal consumption.

The objective of this utility model is to increase the thermo-aerodynamic characteristics of a finned tube, to increase its rigidity and reliability.

The problem in the utility model — the finned tube of a heat-exchange tube bundle of an air-cooled gas cooling apparatus — is solved by the fact that it contains the body of the heat-exchange tube and external fins, which create sections of aerodynamic shading of different intensities in the transverse cooling flow of the external heat-exchange medium in a conditional

a plane normal to the vector of the aforementioned flow of the external heat exchange medium and passing through the central longitudinal axis of the pipe: full aerodynamic shading, corresponding to the projection area onto the indicated plane of the unit length of the pipe body proper, without taking into account finning, and incomplete aerodynamic shading, corresponding to the total projection area to the indicated section plane fins of a unit length of a finned tube bounded on each side of a conditional line drawn along the tops of the ribs, minus the area for complete aerodynamic shading created by the body of the pipe without taking into account fins, the average specific aerodynamic shading area over the radius of the fins in the areas of projection of the fins on the indicated plane per unit length of the pipe is 0.08-0.55.

The ratio of the projection areas onto the indicated plane of the shading areas of different intensities to their sum can be respectively (0.30-0.80): 1 and (0.21-0.79): 1.

The finned tube can be made no less than a two-layer material of different thermal conductivity.

At least the outer layer of the pipe is made of a material with higher thermal conductivity than the inner layer.

The finned tube may be bimetallic.

The outer layer of the pipe and its fins can be made of highly heat-conducting metal or alloys, mainly of aluminum alloy with a thermal conductivity of at least 5% higher than the thermal conductivity of the material of the inner layer of the pipe, which is preferably used steel.

The outer layer of the pipe and its fins can be made of copper or copper-containing alloys.

The outer layer of the pipe and its fins can be made of high-strength and resistant to aggressive media material, mainly from titanium or titanium-containing alloys.

The outer surface of the pipe and its fins can be coated with a highly thermally conductive and resistant to aggressive media material, for example, an aluminum or copper layer deposited by anodizing or spraying, or

cladding.

The fins of the pipe can be made in the form of a spiral from a tape wound onto the pipe and attached to its body, or in the form of ribs formed by knurling the outer layer of the pipe.

The outer diameter of the pipe to the base of the ribs is from 15 mm to 45 mm. The wall thickness of the pipe can range from 0.9 to 3.5 mm. The total height of the pipe ribs can be from 0.27d to 0.85d, where d is the external diameter of the pipe body without ribbing.

The total height of the pipe ribs can range from 5 mm to 22 mm. The ribs of the pipe can be made with a thickness in their outer diameter of 0.3 mm to 2.5 mm, and in the mating zone with the outer surface of the pipe, from 0.5 mm to 3.5 mm, and in this zone the rib is mated with pipe along a curve whose radius is not less than half the thickness of the ribs in the mating zone.

The finned tube can be made bimetallic with an external diameter of the inner supporting pipe of 25 mm, a wall thickness of 1.5-2.0 mm, a full height of the ribs 15-20 mm, a thickness of the ribs on its outer diameter of 0.5 mm, and in the zone mating with the outer surface of the pipe 0.8 mm, and the thickness of the outer layer of the pipe is 1-1.5 mm

The technical result provided by this utility model consists in increasing the thermo-aerodynamic characteristics and cost-effectiveness of a finned tube by optimizing the finning parameters, which ensures optimal material consumption, weight characteristics and laboriousness of manufacturing.

The essence of the utility model is illustrated by drawings, which depict:

figure 1 - finned tube bundle of heat exchange tubes ABO gas;

figure 2 is a fragment of a finned heat exchange tube ABO gas, in the context;

figure 3 - node a in figure 1. figure 4 - node B in figure 2.

The finned tube of the bundle of heat exchangers of the ABO gas contains the actual body 1 of the heat exchange pipe and the outer fins 2. The body 1 and the fins 2 create in the transverse cooling stream of the external heat exchange medium sections of aerodynamic shading of different intensities in the conventional

the plane normal to the vector of the aforementioned flow of the external heat transfer medium and passing through the central longitudinal axis of the pipe, namely, the full aerodynamic shading section 3 corresponding to the projection area onto the indicated plane of the unit length of the pipe body 1 without taking into account finning and the incomplete aerodynamic shading section 4 corresponding to the total the projection area on the specified plane of the finning sections is 2 units of the length of the finned tube, bounded on each side of the conditional line drawn along the In other words, minus the area of total aerodynamic shading created by the body of the pipe 1 without taking into account the fins, the average specific radius of the aerodynamic shading in the sections of the projection of the fins 2 onto the indicated plane per unit length of the pipe is equal to 0.08-0.55 over the radius of the fins 2.

In this case, the ratio of the projection areas onto the indicated plane of the said shading sections 3 and 4 of different intensities to their sum is respectively (0.30-0.80): 1 and (0.21-0.79): 1.

The finned tube can be made no less than a two-layer material of different thermal conductivity.

At least the outer layer 5 of the pipe is made of a material with higher thermal conductivity than the inner 6 layer.

The finned tube may be bimetallic.

The outer layer 5 of the pipe and its fins 2 can be made of highly heat-conducting metal or alloys, mainly aluminum alloy with a thermal conductivity of at least 5% higher than the thermal conductivity of the material of the inner layer of the pipe, which is preferably used steel.

The outer layer 5 of the pipe and its fins 2 can be made of copper or copper-containing alloys.

The outer layer of the pipe 5 and its fins 2 can be made of high strength and resistant to aggressive media material, mainly titanium or titanium alloys.

The outer surface of the pipe and its fins can be coated with highly heat-conducting and resistant to aggressive media material, for example,

a layer of aluminum or copper deposited by anodizing, or spraying, or cladding.

The fin 2 of the pipe can be made in the form of a spiral made of a tape wound on the pipe and attached to its body or in the form of ribs 7 formed by knurling the outer layer of the pipe.

The outer diameter of the pipe is between 15 mm and 45 mm.

The thickness 6 of the pipe wall to the base of the ribs can be from 0.9 to 3.5 mm.

The total height h of the fins of the pipe fins may be from 0.27d to 0.85d, where d is the external diameter of the pipe body without fins, preferably from 5 mm to 22 mm.

The ribs of the pipe can be made of thickness n according to their outer diameter, which is from 0.3 mm to 2.5 mm, and in the interface zone with the outer surface of the pipe m, from 0.5 mm to 3.5 mm, and in this zone mated to the pipe along a curve whose radius R is not less than half the thickness of the ribs in the mating zone.

The finned tube can be made bimetallic with an outer diameter d _{1 of the} inner supporting pipe, which is 25 mm, a wall thickness of 51.5-2 mm, a full height h of fins 15-20 mm, a thickness of f ribs on its outer diameter of 0.5 mm, and in the mating zone with the outer surface of the outer layer of the pipe m is 0.8 mm, and the thickness of the outer layer of the pipe is 1-1.5 mm.

The proposed device is a finned tube of a bundle of heat exchange tubes of an air-cooled gas two-section gas cooling apparatus with b fans, operates as follows. When a cooling coolant (air) with a temperature of 27 ° C is supplied to a bundle of finned heat-exchange pipes of each section through which cooled natural gas is transported at the inlet to the air-conditioning unit with a pressure of 8.35 MPa and a temperature of 60 ° C inlet after compression, air flows around the tube bundle and contact heat transfer with gas cooling at the outlet up to 40 ° С with gas pressure losses less than 0.03 MPa. In this case, due to the optimization of the parameters of the finned tubes of the beam increasing their thermo-aerodynamic characteristics and improving the aerodynamic conditions of the flow of the coolant around the beam,

the total area of the heat exchange surface increases due to the optimization of finning of pipes in the bundle.

The proposed utility model by optimizing the parameters of the finned beam tubes will increase their thermo-aerodynamic characteristics and improve the conditions of the flow around the tube bundle with a working medium. This will provide an increase in the thermal efficiency of the apparatus with a minimum metal consumption of the finned pipe structure, and, consequently, the economy of the entire bundle of heat-exchanging tubes of the ABO gas during its manufacture and operation.

Claims (16)

1. The finned tube of the heat exchange tube bundle of the gas air cooling apparatus, characterized in that it contains the body of the heat exchanger tube and external fins, creating aerodynamic shading sections of different intensities in the transverse cooling flow of the external heat transfer medium in a plane normal to the external heat transfer medium flow vector and passing through the central longitudinal axis of the pipe: complete aerodynamic shading corresponding to the projection area on the specified unit length plane s the actual pipe body without taking into account finning and incomplete aerodynamic shading, corresponding to the total projection area on the indicated plane of the finning sections per unit length of the finned tube, bounded on each side of the straight line drawn along the tops of the ribs, minus the total aerodynamic shading created by the pipe body without it accounting for fins, while the average specific radius of the fins in the radius of fins in the areas of projection of the fins on the specified plane per unit length t the rub is 0.08-0.55. 2. The finned tube according to claim 1, characterized in that the ratio of the projection areas onto the indicated plane of the shading sections of different intensities to their sum is respectively (0.30-0.80): 1 and (0.21-0.79): 1. 3. The finned tube according to claim 1, characterized in that it is made of not less than two-layer of materials with different thermal conductivity. 4. The finned tube according to claim 3, characterized in that at least the outer layer of the pipe is made of a material with greater thermal conductivity than the inner layer. 5. The finned tube according to claim 3 or 4, characterized in that the pipe is made bimetallic. 6. The finned tube according to claim 5, characterized in that the outer layer of the pipe and its fins are made of highly heat-conducting metal or alloys, mainly aluminum alloy with a thermal conductivity of at least 5% higher than the thermal conductivity of the material of the inner layer of the pipe, which is used as preferably steel. 7. The finned tube according to claim 5, characterized in that the outer layer of the tube and its finning are made of copper or copper-containing alloys. 8. The finned tube according to claim 5, characterized in that the outer layer of the pipe and its finning are made of a high-strength and resistant to aggressive media material, mainly from titanium or titanium-containing alloys. 9. The finned tube according to claim 5, characterized in that the outer surface of the tube and its finning are coated with a highly thermally conductive and resistant to aggressive media material, for example, an aluminum or copper layer deposited by anodizing, sputtering, or cladding. 10. The finned tube according to claim 3, characterized in that the finning of the pipe is made in the form of a spiral made of a tape wound on the pipe and attached to its body or in the form of ribs formed by knurling the outer layer of the pipe. 11. The finned tube according to claim 1, characterized in that the outer diameter of the pipe to the base of the ribs is from 15 to 45 mm. 12. The finned tube according to claim 1, characterized in that the wall thickness of the pipe is from 0.9 to 3.5 mm 13. The finned tube according to claim 1, characterized in that the total height of the ribs of the pipe is from 0.27d to 0.85d, where d is the outer diameter of the pipe body without ribbing. 14. The finned tube of claim 13, wherein the total height of the ribs of the pipe is from 5.0 to 22.0 mm. 15. The finned tube according to claim 1, characterized in that the ribs of the pipe are made with a thickness of their outer diameter of 0.3 to 2.5 mm, and in the interface with the outer surface of the pipe from 0.5 to 3.5 mm, moreover, in this zone the rib is conjugated to the pipe in a curve whose radius is not less than half the thickness of the rib in the mating zone. 16. The finned tube according to claim 1, characterized in that it is made bimetallic with an external diameter of the inner supporting pipe of 25 mm, a wall thickness of 1.5-2.0 mm, a full height of the ribs 15-20 mm, the thickness of the ribs on it the outer diameter of 0.5 mm, and in the interface with the outer surface of the outer layer of the pipe - 0.8 mm, and the thickness of the outer layer of the pipe is 1-1.5 mm