SU549672A1 - Surface condenser - Google Patents

Description

vapor-air mixture and reducing the number of ejectors.

The goal is to achieve a tel1 that, in a known surface condenser containing longitudinally after; 1, ovally connected along cooling water and sections separated by intermediate water chambers in which the tube bundles of air coolers are interconnected by an overflow pipe, in each intermediate water chamber There are two air coolers of adjacent sections of the duct, and in the latter there is a by-pass pipe connecting the suction chamber of the air cooler to the next section along the water section with the chamber supply the previous one.

In this case, the cross-section of the box corresponds to the cross-section of the air coolers.

FIG. 1 shows a schematic longitudinal capacitor, general view; pas figs. 2 - section A-A, FIG. one; pas figs. 3 - section bb, fig. one; in fig. 4 - section bb, fig. one

The surface condenser consists of sections J and 2, containing respectively the main tube bundles 3 and 4 of the cooling surface and the tube bundles of the air coolers 5 and 6. The cooling water is supplied through the inlet water chamber 7, and the outlet through the chamber 8. Sections / and 2 They are divided among themselves by cooling water in the intermediate water chamber 5. Air coolers 5 and f in their lower part have supply chambers 10 and // steam-air mixture. In this case, the supply chamber W of the vapor-air mixture is connected to the space in the intermediate water chamber 9 by the window 12, made in the tube plate 13 of the section /. Air coolers 5 and 6 in the upper part have suction chambers 14 and 15 of the steam-air mixture, respectively, formed by shields / b installed in the steam space of sections 1 and 2 of the condenser. The suction chamber 15 is connected to the intermediate water chamber 9 by means of a window 17, made in tube plate 18 of section 2, and the suction chamber 14 is connected to the ejector pipe 19 (not shown in the drawings). In the intermediate water chamber 9, a duct 20 is made, connecting the air coolers 5 and (5 over cooling water, and the overflow pipe 21, in which the vapor-air mixture suction section 17 of section 2, which follows the water flow, is connected to the previous air vapor supply window 12 in the course of the water section 1.

In the lower part of the sections / and 2 are made of the condensate traps 22 and 23, interconnected by means of a hydraulic lock 24.

When the steam turbine installation is in operation, the cooling water flows through the inlet

water chamber 7 into the cooling surface of the main tube bundle 5 and air cooler 5 sections /. Further, the heated water enters the cooling surface of the main tube bundle 4 and the air cooler 6 of section 2 through the intermediate water chamber 9, with the flow of cooling water of the main tube bundles 3 and 4 I

air coolers 5 and 5 are insulated from each other by box 20, connected, for example, by welding to pipe boards / -7 and 18. Installing such a box in an intermediate water chamber 9 eliminates mixing “hot water from the main flow of the tube bundle 3 and“ cold water from the air cooler 5, which provides deep cooling of the vapor-air mixture in section 2. Next, the cooling water from the main pipe bundle 4 and the air cooler 6 of section 2 is mixed in the outlet water chamber 8. In the case of using heat "heated water in the outlet In a water chamber 8, it is advisable to perform a separate discharge of water.

The steam-air mixture enters the supply chamber // air cooler 6 ″ by hot subsequent section along the water course 2 and further into the suction chamber 15 connected to the window / 7. Since in the air cooler 6 the water is cooler, compared with the water temperature, the efficiency of the air cooler from the main tube bundle 3 increases significantly. In the intermediate water chamber 9, the vapor-air

the mixture through the bypass pipe 21 is bypassed through the window 12 into the chamber of the inlet 10 of the air cooler and is sucked through the chamber of the suction 14 and the pipe 19 by the ejector. The efficiency of the air cooler 5 "cold section / in this case also increases, since its underload is significantly reduced. In addition, with this vapor-air mixture suction system, the number of ejectors is reduced. The condensate from the condensate collection section 22 / enters the condensate collection unit 23 of section 2 through a water lock 24.

Claims (2)

1. Patent of England No. 1027233, cl. F 4e 1966 2. US patent No. 2998227, cl. 165-97, 5 1961 / / U 22 u2 "/ 5 J ". ,, I  (; // / / fus3 FIG 4