RU13500U1 - STRUCTURED NOZZLE BLOCK FOR HEAT AND MASS EXCHANGE UNITS - Google Patents

Description

Utility model. Block structured nozzles for heat and mass transfer apparatus.

The utility model relates to chemical and petrochemical engineering, in particular to nozzle designs used in apparatuses for various heat and mass transfer processes (rectification, absorption, condensation, heating, cooling, etc.).

From the prior art, the SULZER nozzle design is known, comprising individual blocks consisting of vertical corrugated perforated metal sheets (approaching the foil in thickness), the corrugations of which are located at an angle to the vertical. In adjacent sheets, the corrugations have the same in size, but opposite in direction, angle of inclination to the vertical, see Foreign packing devices of mass transfer equipment, TsINTIHIMNEFTEMASH, Moscow, 1982. with. 11-13.

As a prototype of a utility model, the authors selected a block of structured packing of heat and mass transfer apparatus, consisting of vertical corrugated sheets with oblique corrugation, and in adjacent sheets the corrugation has the same size but opposite in direction to the vertical angle, and the entire corrugated surface of the sheets is perforated by rows of grooves equipped with visors with different bending angles, see A.S. USSR No. 1082470. M. Cl. BO 1J 19/30, 1983

The nozzles of the analogue and prototype have a low hydraulic resistance, however, their common drawback is the relatively low efficiency, due to the underdeveloped contact surface of the interacting phases.

The technical problem to which the utility model is directed is to reduce the specific resistance of the nozzle (lowering the parameter (Dp / t |), i.e., reducing the resistance of the nozzle layer equivalent to one theoretical plate and increasing the efficiency of mass transfer.

The solution to this problem is ensured by the fact that the structured nozzle block for heat and mass transfer apparatus, including vertically arranged corrugated perforated sheets with corrugation in adjacent sheets with the same inclination and opposite in direction, according to the utility model, the corrugated vertical sheets are made of grooves 6 here is s / 2b

of an air-drawn metal sheet with a diamond-shaped shape of notches and curved jumpers between them, the width of which is 1.2-25, where 8 is the thickness of the sheet, while the angle of inclination of the jumpers to the surface of the sheet is 35-75 °, and the live section of each is expanded corrugated sheet is 30-75% of its total area. In preferred embodiments of the utility model, the large diagonals of the diamond-shaped notches can be oriented either vertically or horizontally with respect to the working position of the sheets in the nozzle block. In all embodiments, the angle of inclination of the corrugations to the vertical is 20-70 °, and the bending angle of the sheets at the vertices of the corrugations is 80-140 °. In addition, it is preferable that adjacent sheets in the nozzle blocks are mounted with mirror symmetry of the bending direction of the bridges between the diamond-shaped notches.

The technical result of using the proposed utility model is to reduce the specific resistance of the nozzle (lowering the parameter (Ap / c), i.e., reducing the resistance of the nozzle layer equivalent to one theoretical plate. This follows from the fact that one of the main parameters characterizing the performance of the nozzles ( especially if they are used in apparatuses operating under vacuum), the parameter - Др / г | - ie the resistance of the nozzle layer equivalent to one theoretical plate (where Др is the resistance, g is the efficiency) is the parameter. the smaller the value of Lr / t), the more efficient the nozzle and the lower the energy cost of conducting the heat and mass transfer process. Studies have shown that with an increase in the area of perforation of the sheets (live section of the sheets), the resistance (Dp) of the nozzle decreases faster than the efficiency (t |), and in general the parameter (Dp / t |) decreases.

The utility model is illustrated by drawings, where:

In FIG. 1 schematically shows a General view of the mass transfer apparatus with a nozzle;

in FIG. 2 - shows the nozzle block;

in FIG. 3 shows a section AA of FIG. 1;

in FIG. 4 - shows a sheet of the nozzle block;

in FIG. 5 - section BB is shown in FIG. 4; 4 in FIG. 6 - shows a view In figure 5

in FIG. 7 is a section F-F of FIG. 6.

A regular nozzle for heat and mass transfer apparatus includes blocks 1 of vertical corrugated metal sheets 2. In the nozzle blocks, adjacent sheets 2 have the same but opposite angle of inclination of the corrugations 3 to the vertical. Vertical corrugated sheets 2 are made

of expanded metal sheets with a diamond-shaped shape of notches 4 Between the notches 4 there are jumpers 5, the width of which is 1.2-25 where 5 is the thickness of the sheet 2 The angle of inclination of the jumpers 5 to the surface of the sheets 2 is 35-75 °, and the live section of each perforated corrugated sheet is 30-75% of its total area

In preferred embodiments, the large diagonals d of the diamond-shaped slots 4 are oriented either vertically or horizontally with respect to the working position of the sheets 2 in the nozzle blocks. In all embodiments, it is preferable that the angle of inclination of the corrugations 3 to the vertical is 35-75 °, and the bend angle of the sheets 2 at the tops of the corrugations 3 was 80-140 °. In addition, adjacent sheets 2 in the nozzle blocks 1 are installed with mirror symmetry of the direction of the bending of the bridges between the diamond-shaped notches

The nozzle for heat and mass transfer apparatus works as follows

Gas (steam) is supplied to the apparatus 6 through the corresponding pipe 7, and the liquid from above through the nozzle 8 enters the liquid distributor 9, from where it enters the nozzle collected from blocks 1

The flow of the vapor (gas) phase flows under the lower edge sections of the vertical corrugated sheets 2 of the block 1 and is divided into jets moving along intersecting channels formed by corrugations of 3 adjacent sheets 2 At the crossing sections of the channels (located regularly throughout the block volume), the steam jet ( gas) are turbulized and mixed together

Depending on the position of the curved jumpers 5 with respect to the flow of the gas (vapor) phase, the boundary layers of the jets either leak onto the jumpers and are deflected by them through the cutouts 4 into adjacent channels, or (if the curved jumpers are located along the flow of the gas (vapor) phase), ejection of the gas (vapor) phase through the cutouts 4 from adjacent channels

Thus, during the movement of the gas (vapor) phase in the nozzle block, movement occurs along intersecting channels, as well as movement between the sheets of the block through the cutouts 4 in sheets 2. Moreover, jets of gas (steam) are regularly turbulized not only in the areas of channel crossing, but and when the boundary layers of the jets pass through adjacent channels (through the cutouts 4), the mirror arrangement of the curved jumpers 4 in adjacent sheets 2 leads to a zigzag motion of the gas (vapor) phase between the sheets 2 of the nozzle block 1 of the (vapor) phase moving along the channels formed by the corrugations of the sheets and the gas (vapor) phase moving

through the grooves 4 is determined by the angle of inclination of the corrugations, the living cross section of expanded metal corrugated sheets 2 and the magnitude of the bending of the jumpers 5.

The liquid phase entering the nozzle blocks 1 from the liquid distributor 9 flows downward in the form of film jets along branched curved jumpers 5 slots 4 sheets 2. Due to the Coanda effect, the liquid jets “stick to the jumpers 5. (For information, the Coanda effect is characterized by the sticking of liquid jets to a solid surface; for more details on this effect, see, for example, the book by G.V. Smirnov, “Born by the Whirlwind, M., Knowledge, 1982, from 178-182.)

At the points of convergence (nodes) of the jumpers 5 from adjacent cuts 4, the liquid jets merge and then redistribute to the lower jumpers and nodes, which ensures that the entire surface of the sheets 2 is wetted by the liquid phase. At the places where adjacent block sheets adjoin each other, the liquid phase has the possibility of partial overflowing from sheet to sheet.

Heat and mass transfer between the contacting phases is as follows.

The liquid phase flowing in the form of streams along the jumpers and partially accumulating at the convergence nodes of the jumpers is intensively blown by gas (steam) jets, while under the action of gas (steam) jets, part of the liquid breaks off and is transferred to other parts of the sheet surface in the form of tiny drops. due to the fact that the notches 4 are diamond-shaped, when liquid accumulates in the nodes (i.e., at the intersections) of the jumpers 5, a part of the liquid in the form of a film “tightens the surface of the notch 4, locally changing the hydraulic resistance in this section, which than the velocity of jet accompanied by entrainment of liquid in adjacent areas, which resistance begins to rise (due to settling during the storing entrained liquid). In turn, this leads to a local increase in the pressure of the gas phase and rupture of the liquid films on the cuts 4. The torn films of the liquid phase in the form of tiny droplets are transferred to other sections of the sheets 2 and the process is repeated, while the contact surfaces are updated due to rupture of the liquid films, the area of which increases many times.

Next, the vapor (gas) enters the next overlying block where the mass transfer process is repeated.

area and transfer to another area where due to the subsidence of the fluid increases the hydraulic resistance, leading to the overlap of the bypass.

Thus, in the proposed nozzle, both film, countercurrent contact of the interacting phases, and contact in the droplet form are realized.

The orientation of the diamond-shaped slots in the nozzle sheets depends on the viscosity of the liquid phase; with higher viscosity, the vertical orientation of the large diagonals of the diamond-shaped cuts 4 is preferred; at lower viscosity, horizontal orientation of these diagonals is preferable. Typically, when choosing horizontal or vertical orientation of the slots, the device’s performance in terms of gas (bet) and liquid is known, including the characteristics of the liquid phase.

It should also be noted that the turbulization of the boundary layers of the jets by curved bridges 5 intensifies the contact of the interacting phases and significantly increases the efficiency of heat and mass transfer. The efficiency of heat and mass transfer increases, also due to the effective redistribution of the flows of vapor (gas) and liquid phases over the cross section of the block and the nozzle as a whole, as well as an increased contact time of the interacting phases.

When making contact of the phases with relatively low flow rates for liquid and gas (steam), liquid films on the cutouts 4 are not formed. In this case, the film-countercurrent contact of the interacting phases is predominantly realized.

To determine the optimal live section of the sheets, with a minimal influence of the parameter (Ap / t)), the authors tested nozzle blocks with sheets having different live sections and different widths of the bridges between the cuts, as well as different angles of inclination of the corrugations to the vertical and angles at the vertices of the corrugations .

As a result of research, it was found that the use of expanded metal as a structural material for the manufacture of nozzle blocks has the following advantages:

 Due to the fact that during the manufacturing process of the expanded metal sheet (its drawing), the bridges between the grooves are bent (rotated) unidirectionally oriented at an angle to the plane of the sheet, they are essentially guiding elements for the jets of the vapor (gas) phase. From the point of view of the redistribution of the gas (vapor) phase, the most optimal is the width of the bridges between the perforations, at which it is 1.2-25 (where 5 is the thickness of the metal sheet). With the indicated ratio of the width of the lintels and the thickness of the sheet, the vapor (gas) phase is most effectively redistributed over the cross section of the nozzle, thereby increasing its efficiency.

 The intersections of the jumpers 5 between the cutouts form the nodes on which the flowing liquid film accumulates moving along the jumpers 5, which is redistributed across the jumpers 5 of the adjacent cuts, i.e. after each node the number of jumpers along which the liquid is distributed doubles. This leads to the redistribution of fluid over the entire cross-section of the nozzle and eliminates the brook mode of movement of the fluid film on the surface of the sheet.

The use of expanded metal in principle allows you to develop an arbitrarily large living section of the vertical sheets of the nozzle.

The larger the live section of the expanded sheet, the lower the metal consumption of the nozzle. The additional surfaces formed in the manufacture of the expanded metal in the places of the grooves increase the total contact surface of the phases on the nozzle, which (depending on the size of the live section, the width of the bridges between the grooves and the thickness of the expanded metal) compensates for the loss in the area of the sheets when they are drawn and does not reduce the efficiency ( d |) nozzles.

The value of the indicator (Ap / tj) is reduced when using expanded metal sheets with a live section of 30-70%, while the minimum value of this indicator is achieved with a live section of 50 - 60%.

The optimal (depending on the ratio of the magnitude of the vapor (gas) and liquid loads) angles at the top of the corrugations are 80 - 140 ° and the angles of inclination of the corrugations to the vertical 35 -70 °.

The most favorable for uniform redistribution of the liquid phase on the expanded metal sheet is the diamond-shaped shape of the notches.

The studies also found that the proposed nozzle is effective in a wide range of operating modes, which is achieved by the optimal redistribution of the contacting phases in the volume of the nozzle and the intensification of their contact.

Claims (5)

1. Block structured nozzles for heat and mass transfer apparatus, including vertically arranged corrugated perforated sheets with inclined corrugation, the corrugations of which in adjacent sheets have the same but opposite angle to the vertical, characterized in that the corrugated vertical sheets are made of expanded metal sheet with live a cross-section of 50-75% and with a diamond-shaped shape of notches, the width of the jumpers between which is 1.2-2.0δ, where δ is the thickness of the sheet, while the angle of inclination of the ek to the sheet surface is 35-75 ^o, and an open area of each expanded metal corrugated sheet is 35-75% of its area.  2. The structured nozzle block according to claim 1, characterized in that the large diagonals of the diamond-shaped notches are oriented vertically in accordance with the working position of the sheets in the nozzle block.  3. The structured nozzle block according to claim 1, characterized in that the smaller diagonals of the diamond-shaped notches are oriented vertically in accordance with the working position of the sheets in the nozzle block. 4. Block structured nozzles according to any one of claims 1 to 3, characterized in that the angle of inclination of the corrugations to the vertical is 20-70 ^o . 5. The structured nozzle block according to any one of claims 1 to 4, characterized in that adjacent sheets in the nozzle block are installed with mirror symmetry of the bending direction of the bridges between the diamond-shaped notches.