RU2008607C1 - Sprinkler element of counterflow cooling tower and sprinkler unit of counterflow cooling tower (versions) - Google Patents

Abstract

FIELD: thermal power engineering. SUBSTANCE: sprinkler element of counterflow cooling tower has corrugated plate at angle to edge. One side of plate has horizontal rows of ridges of equal height in each row. Rows are spaced apart at distances reducing towards of one of plate edges. Ridges of adjacent rows are of different height reducing in same direction. Their apexes are on inclined plane to that crossing bases of ridges at angle of 5 to 15 deg. Sprinkler unit of first version is built up of vertical plates; adjacent plates have different direction of corrugations. Plates are installed with their ridges on one side to form ducts having either flat corrugated walls or walls with ridges. Sprinkler unit of second version has its plates installed so that their ridges are opposing each other to form alternating ducts of varying and constant flow area. Ridges function as turbulizing means. EFFECT: improved efficiency. 8 cl, 6 dwg

Description

 The invention relates to a power system, in particular to sprinklers of cooling towers.

 Known element countercurrent cooling tower containing a smooth plate, located on both sides of the plate alternating protrusions and depressions, vertical corrugated sections, alternating and symmetrically made relative to the protrusions [1].

 The main disadvantage of the element is the low efficiency of heat and mass transfer when installed in a cooling tower due to the insufficiently developed contact surface between the air and the sprayed water, and the absence of turbulizing agents.

 The closest to the invention in technical essence and the achieved result is an element of the sprinkler countercurrent cooling tower, made with corrugations in the form of a continuous wave, located at an angle to the edge of the element, and equipped with horizontal rows of protrusions of the same height in each row [2].

 The main disadvantage of such an element is the insufficiently high efficiency of heat and mass transfer in the cooling tower, especially under various modes of operation.

 The invention eliminates this disadvantage.

The technical result is achieved by the fact that in the irrigation element of the counterflow tower made with corrugations in the form of a continuous wave, located at an angle to the edge of the element, and provided with horizontal rows of protrusions of the same height in each row, the protrusions are made on one side of the element with a step between the rows, decreasing in the direction of one of its edges, the protrusions of adjacent rows are made with different heights, decreasing in the direction of the same edge, and their vertices are located in a plane inclined to the plane walking through the base of the protrusions, at an angle of 5.. . 15 ^about . In this case, the protrusions are made with a cross section of a rectangular or curved shape.

 A sprinkler block is also known, containing vertically mirrored plates with vertical corrugated sections and alternating protrusions and depressions symmetrically located on both sides of the sections [1].

 Using protrusions and depressions, high rigidity of the block and manufacturability of the assembly are achieved. However, there is a significant drawback, which is the low efficiency of heat and mass transfer due to the insignificant turbulizing ability of the plate elements.

 Closest to the invention in technical essence and the achieved result is a countercurrent cooling tower sprinkler unit containing vertically mounted plate elements made with corrugations in the form of a continuous wave located at an angle to the edge of the element and provided with horizontal rows of protrusions of the same height in each row, and adjacent the elements are made with the opposite slope of the corrugations [2].

 The main disadvantage of this unit is the insufficiently high heat and mass transfer efficiency due to the low intensification of the heat transfer process in the channels between the plates.

 The invention eliminates this disadvantage.

 According to the first embodiment, the technical result is achieved by the fact that in the irrigation unit of the counterflow tower containing vertically mounted plate elements made with corrugations in the form of a continuous wave located at an angle to the edge of the element and provided with horizontal rows of protrusions of the same height in each row, and adjacent elements made with the opposite slope of the corrugations, when performing the protrusions of each element on one of its sides and with a height decreasing in the direction of one of its edges, Py of all elements of the block are oriented in one direction. In this case, the protrusions of the maximum height of all elements are made either at the upper end of the block, or at the opposite ends of the block.

 According to the second embodiment, the technical result is achieved in that in the irrigation unit of the counterflow tower when performing protrusions of each element on one of its sides and with a height decreasing in the direction of one of its edges, adjacent elements are installed with the opposite orientation of the protrusions with the formation of alternating channels of constant and variable flow area. The protrusions of the maximum height of adjacent elements are made at the upper end of the block or at the opposite ends of the block.

 In FIG. 1 shows a sprinkler element, general view; in FIG. 2 is a section AA in FIG. 1; in FIG. 3 is a section BB in FIG. 1; in FIG. 4 - sprinkler block, general view; in FIG. 5 is a side view when performing the block according to the first embodiment; in FIG. 6 is a side view when performing the block according to the second embodiment.

The irrigation element of the counterflow cooling tower contains a plate 1 with corrugations 2 in the form of a continuous wave, located at an angle to the edge of the plate 1. On one side of the element there are protrusions 3-7 of equal height arranged in horizontal rows in each row. The rows of protrusions are made in increments decreasing in the direction of one of its edges (for example, from top to bottom, Fig. 2). The protrusions 3-7 in adjacent rows are made with different heights, decreasing in the indicated direction, and their vertices are located in a plane inclined to the plane passing through the base of the protrusions 3-7, at an angle of 5-15 ^about . The protrusions 3-7 can be made with a cross section of a rectangular or curved shape.

 The sprinkler block according to the first embodiment contains vertically mounted plate elements 1, and adjacent elements are made with the opposite direction of the corrugations 2 (Fig. 4), and the protrusions 3-7 are made on one side with a height decreasing in the direction of one of the edges (top down), and oriented in one direction (Fig. 5). In this case, the protrusions of the maximum height of all elements can be made at the upper end of the block or these protrusions of adjacent elements are made at the opposite ends of the block. With this installation of the plates 1, channels 8 are formed in the block either with smooth corrugated walls or with protrusions.

 According to a second embodiment of the block, adjacent elements of the plate 1 are installed with the opposite orientation of the protrusions 3-7 with the formation of alternating channels 9 and 10, respectively, of constant and variable passage section (Fig. 6). Moreover, according to the second embodiment of the block, the protrusions of the maximum height of adjacent plate elements 1 can also be made either at the upper end or at the opposite ends.

 Under the operating conditions of the sprinkler in the cooling tower, heat and mass transfer between the water sprayed from above and the air coming from below was carried out under counterflow conditions. A film of water on the surface of the plates 1 flows down, mainly along the inclined corrugations 2, interacting with air. During the flow around protrusions 3–7, the nature of the film flow is disturbed, the film is destroyed by the upward flow of air, and heat exchange occurs in channels 8–10 in the case of a droplet state of water. When water moves from top to bottom during its interaction with protrusions 3-7, which are turbulizers, the film thickness decreases and, to maintain the efficiency of heat and mass transfer, the height of the protrusions should decrease. However, under variable operating conditions of the cooling tower, it is more expedient to run channels 9 and 10 with different turbulence efficiencies, i.e., with different changes in the height of the protrusions 3-7 in adjacent plates 1. (56) 1. USSR author's certificate N 1442806, cl. F 28 F 25/02, published. 1987.

 2. EP N 0293003, cl. B 01 D 53/18, published. 1988.

Claims (7)

1. The irrigation element of the counterflow cooling tower, made with corrugations in the form of a continuous wave, located at an angle to the edge of the element, and provided with horizontal rows of protrusions of the same height in each row, characterized in that the protrusions are made on one side of the element with a pitch between rows decreasing in the direction of one of its edges, the protrusions of adjacent rows are made with different heights, decreasing in the direction of the same edge, and their vertices are located in a plane inclined to the plane passing through the base I have protrusions at an angle of 5 - 15 ^o .  2. The element according to claim 1, characterized in that the protrusions are made with a cross section of a rectangular or curved shape.  3. The irrigation unit countercurrent cooling tower containing vertically mounted plate elements made with corrugations in the form of a continuous wave, located at an angle to the edge of the element, and equipped with horizontal rows of protrusions of the same height in each row, and adjacent elements are made with the opposite inclination of the corrugations, characterized in that when performing protrusions of each element on one of its sides and with a height decreasing in the direction of one of its edges, the protrusions of all elements of the block are oriented in the same direction equalization.  4. The block according to claim 3, characterized in that the protrusions of the maximum height of all elements are made at the upper end of the block. 5. The block according to claim 3, characterized in that the protrusions of the maximum height of adjacent elements are made at opposite ends of the block
6. The irrigation unit countercurrent cooling tower containing vertically mounted plate elements made with corrugations in the form of a continuous wave, located at an angle to the edge of the element, and provided with horizontal rows of protrusions of the same height in each row, and adjacent elements are made with the opposite inclination of the corrugations, characterized in that when performing protrusions of each element on one of its sides and with a height decreasing in the direction of one of its edges, adjacent elements are installed with the opposite orientation protrusions with the formation of alternating channels of constant and variable flow area.  7. The block according to claim 6, characterized in that the protrusions of the maximum height of adjacent elements are made at the upper end of the block.  8. The block according to claim 6, characterized in that the protrusions of the maximum height of adjacent elements are made at opposite ends of the block.

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