RU222955U1 - Nozzle element for nozzle devices - Google Patents

Abstract

The utility model relates to elements of packings for packing devices in the chemical, oil and gas, food and related industries and can be used to carry out absorption, desorption, rectification and other heat and mass transfer processes. The purpose of the utility model is to increase the surface area of phase contact, which will intensify processes in packed devices. This result is achieved due to the fact that the cross-section of the proposed nozzle element for attachment devices has a cardioid shape. The design of a packing element for packed devices, the cross section of which has a cardioid shape, makes it possible to increase the surface area of phase contact and, thereby, intensify the processes in the packed devices. An additional increase in the phase contact surface area can be achieved by adding to the nozzle element for nozzles an internal partition in cross section extending from the cusp of the cardioid through the center of the cardioid. If it is necessary to further increase the phase contact surface area, the cross-section of the packing element may have a second internal baffle extending through the center of the cardioid at right angles to the first internal baffle, forming a cruciform internal baffle.

Description

The utility model relates to elements of packings for packing devices in the chemical, oil and gas, food and related industries and can be used for absorption, desorption, rectification and other heat and mass transfer processes.

A well-known element of the nozzle for nozzle devices is the Raschig ring, the cross section of which has the shape of a flat geometric figure [Processes and apparatus of the chemical industry: Textbook for technical schools / P.G. Romankov, M.I. Kurochkina, Yu.Ya. Mozzherii et al. - L.: Chemistry, 1989. - 560 p. (P. 334)].

A disadvantage of the known packing element for packed devices is the small surface area of phase contact, which leads to a decrease in the intensity of processes in the packed devices.

The purpose of the utility model is to increase the surface area of phase contact, which will intensify processes in packed devices.

This result is achieved due to the fact that the cross-section of the proposed nozzle element for attachment devices has a cardioid shape.

The proposed nozzle element for nozzle devices in cross section may have an internal partition extending from the cusp of the cardioid through the center of the cardioid.

The cross-section of the proposed nozzle element may have a second internal baffle extending through the center of the cardioid at right angles to the first internal baffle, forming a cruciform internal baffle.

A three-dimensional model of the proposed nozzle element for nozzle devices according to claim 1 of the utility model formula is presented in Fig. 1. In FIG. Figure 2 shows its cross section.

A three-dimensional model of the proposed nozzle element for nozzle devices according to claim 2 of the utility model formula is presented in Fig. 3. In fig. Figure 4 shows its cross section.

A three-dimensional model of the proposed nozzle element for nozzle devices according to claim 3 of the utility model formula is presented in Fig. 5. In FIG. 6 shows its cross section.

An increase in the phase contact surface area will be observed for two reasons:

Firstly, the presence of a stiffening rib in the form of a cardioid cusp in the proposed nozzle element for nozzle devices increases its strength and stability. Consequently, the proposed nozzle element for nozzle devices will have equal strength and stability with a smaller wall thickness, in comparison with the prototype - the Raschig ring. Reducing the wall thickness of the packing element for packing devices leads to an increase in the area of its internal surface, therefore, the phase contact surface area increases.

Secondly, the perimeter of a cardioid is always equal to the length of the circle in which it is inscribed, but due to the presence of a cardioid cusp, the proposed nozzle element for nozzle devices will occupy less volume in the nozzle layer, in comparison with the prototype - the Raschig ring. Thus, the maximum number of elements in 1 m ³ of the nozzle increases and, consequently, the surface area of phase contact increases.

The design of a packing element for packed devices, the cross section of which has a cardioid shape, makes it possible to increase the surface area of phase contact and, thereby, intensify the processes in the packed devices.

An additional increase in the phase contact surface area can be achieved by adding to the nozzle element for nozzles an internal partition in cross section extending from the cusp of the cardioid through the center of the cardioid.

If it is necessary to further increase the phase contact surface area, the cross-section of the packing element may have a second internal baffle extending through the center of the cardioid at right angles to the first internal baffle, forming a cruciform internal baffle.

Claims (3)

1. An element of a nozzle for nozzle devices, the cross section of which has the shape of a flat geometric figure, characterized in that the flat geometric figure is a cardioid. 2. The nozzle element for nozzle devices according to claim 1, characterized in that in the cross section from the cusp of the cardioid, an internal partition passes through the center of the cardioid. 3. A nozzle element for nozzle devices according to claim 2, characterized in that in cross section a second internal partition passes through the center of the cardioid at a right angle to the internal partition, forming a cruciform internal partition.