HU206408B - Horizontally arranged condenser for liquefying vapours of cooling apparatuses - Google Patents

Abstract

The invention relates to a Rohrbuendelkondensator with increased heat transfer factor for liquefaction of Daempfen, the cooled tubes contained, which are arranged in a limited by a jacket and Roehrenwaenden steam room and over the connecting piece for steam introduction, the Fluentigkeitsabfuehrung and the removal of non-condensable gases. According to the invention, baffles are installed in the vapor space of the condenser either parallel or perpendicular to the cooled tubes. Fig. 3

Description

BACKGROUND OF THE INVENTION The present invention relates to a liquefied condenser for liquefying vapors of refrigeration equipment having a specific heat output (heat transfer coefficient) significantly higher than that of known tubular capacitors.

Batch condensers are known to be used in many industries to liquefy the vapors of a variety of materials by cooling. By way of example, in refrigerating equipment, liquefaction of the evaporated refrigerant, after it is compressed by a compressor, is carried out in a water-cooled tubular condenser.

The circuit arrangement and mode of operation of the known tubular capacitors will be described in more detail below with reference to Figures 1 and 2. Here, it is briefly mentioned that the vapor to be liquefied enters a vapor space through an inlet, where it condenses on the surface of water-cooled pipes mounted in tubular walls. The condensed liquid gathers from the pipes and collects at the bottom of the vapor chamber cover and exits through an outlet. Cooling water is the so-called cooling system. it enters at the inlet of the water cover and flows through the pipes through the baffles built into the water cover as it heats up and then exits through the outlet of the water cover. The unit also has a manifold for removing non-condensable gases. The heat necessary for liquefaction is carried out through the wall of the pipes passing through the steam chamber. The heat output depends on the surface of the pipes, the temperature difference and the heat transfer coefficient. The heat transfer coefficient is known from the following equation.

Reference is made hereafter to a number of references in the literature which describe the state-of-the-art embodiments of tubular capacitors used in refrigeration equipment, as well as their so-called prior art designs. 'K', which is the 'k' factor needed to calculate the heat output.

a) MAAKE-ECKERT: Pohlmann Taschenbuch dér Káltetechnik, Verlag C.F. Müller, 1978, Chapter 7.5.2.1, pp. 281-282. p.

(b) H.L. von CUBE: Lehrbuch Dér Káltetechnik, Verlag C.F. Müller, 1981, Bánd Chapter 1.4.3.1.1, p.

(c) DVORAK-CERVENKA: Industrial Refrigeration Equipment, Technical Book Publisher, 1964,145-152. p.

A disadvantage of the construction of known tubular condensers is that the velocity of the vapor entering the condensation nozzle in the condensation space is greatly reduced, and at some points along the condensation tube surfaces the flow velocity approaches zero. As a consequence, non-condensable gases are adhered to the pipe surfaces in a thick layer, and on the other hand, the concentration (partial pressure) of the non-condensable gases in the vapor space is also very high, resulting in significant condensation degradation.

The tubular condenser with an increased heat transfer coefficient for vapor liquefying of the present invention is intended to greatly reduce the heat transfer coefficient of steam condensation resulting from the presence of non-condensable gases (mostly air) and thereby reduce the condenser power. The invention is based on the discovery that by incorporating baffles in the tubular condenser between the condensation tubes in parallel with the tubes, which reduce the flow cross-section in the flow direction, the vapor flow conditions can be significantly altered and very advantageously condensed.

The use of baffles according to the invention ensures that the vapor introduced into the vapor space is forced to flow much faster, thereby making the non-condensable gas a thinner layer on the surface of the tubes and reducing the concentration of non-condensable gas in the vapor space. As a result, the harmful effects of non-condensable gases are greatly reduced.

Accordingly, the present invention relates to a liquefied condenser for liquefying vapors of condenser refrigeration equipment, which in a manner known per se has a jacketed vapor compartment receiving the vapors to be liquefied, and a bundle of conduits conducting refrigerant therein. It is an object of the present invention to divide the vapor space into at least one baffle parallel to the pipes of the bundle into passageways whose flow cross-section is reduced per passageway.

The design according to the invention has the advantage that the concentration of non-condensable gases present in the vapor chamber is lower due to the higher flow rate compared to the known condensers and also in a thinner layer, thus reducing the heat transfer. In addition, the baffles parallel to the cooling conduits catch the dripping condensate, thereby relieving the cooling conduits underneath from the effect of dripping condensate. Both of these factors result in an increase in the heat transfer coefficient of the capacitor.

An exemplary embodiment of a tubular capacitor with an increased heat transfer coefficient according to the invention will be described in more detail by reference to the drawing, wherein

1 is a sectional view taken along line B-B in FIG.

Figure 2 is a sectional view taken along line A-A of the capacitor of Figure 1, a

Figure 3 is a schematic view of a tubular condenser with an increased heat transfer coefficient according to the present invention, taken along the line D-D, and

Figure 4 is a sectional view taken along the line C-C of the capacitor of Figure 3.

Figures 1 and 2 illustrate an embodiment of a known lying cylinder tubular condenser for refrigeration equipment. The vapor to be liquefied enters at the nozzle (1) into a vapor space (12) enclosed by a jacket (2) where it is deposited on the outer surface of water cooled tubes (3) mounted on a tube wall (4). The condensed liquid from the tubes (3)

EN 206 408 Β Drips at the bottom of the sheath (2) and leaves through the stub (5). The cooling water enters at the inlet (7) on the water cover (6) of the device and is guided through the tubes (3) and guided by the baffles (8) in the water cover (6) and then exits at the outlet (9). The nozzle (10) on the shroud (2) serves to remove non-condensable gases.

The heat removal required for liquefaction is thus through the walls of the tubes (3). The heat output Q is dependent on the surface area F of the tubes (3), the temperature difference At and the heat transfer coefficient k, according to the relationship Q - kxFx At. The heat transfer coefficient k can be calculated from the known relation ka _t λ α ₂ , where _{t is} the heat transfer coefficient of steam condensation, <* 2 is the heat transfer coefficient of water flowing in pipes (3), δ is the thickness of the pipe wall, λ is the thermal conductivity of the pipe wall material.

The literature cited in the introductory part of this specification gives the heat transfer coefficient of known designs of tubular condenser, for example, for the condensation of ammonia in the range k-800-1200 W / m ² K. This is significantly less than 1500-2000 W / m ² K obtained from equation (1) in the analytical calculation of the heat transfer process. This difference can be explained by the fact that equation (1) does not take into account the practical factors that impede the heat transfer, namely the contaminant layers (oil, limescale, etc.) on the outer and inner surfaces of the pipes and the presence of non-condensing gases on the vapor side. .

Non-condensable gases reduce condensation heat transfer for two reasons:

- the non-condensing gas surrounds the heat transfer surface to a thickness determined by the flow conditions, and vapor molecules can only come into direct contact with the condensation surface by diffusion;

The partial pressure of the non-condensable gas present in the vapor space (12) increases the pressure of the condenser, so that the condensation temperature is less than the saturation temperature of the vapor at the condenser pressure;

Figures 3 and 4 illustrate a structural arrangement of a tubular capacitor according to the invention, which differs from the known tubular capacitor structure shown in Figures 1 and 2 in that the steam chamber (11) has baffles (12). steam room as an example! In the embodiment, it is divided into four (a, b, c and d) flights. As the flow cross-section of the passages (a, b, c and d) decreases per passage as shown by the arrows (13) of the steam flow, the velocity decrease due to condensation is compensated and the condensing steam flows horizontally with the arrows (13). is forced to take the road while it collapses. Non-condensable gases are also flowing with the steam and are discharged through the nozzle (10), while the condensed liquid exits the nozzle (5).

Figure 4 also shows that the baffles (11) are inclined from right to left in the drawing, i.e. the baffles (11), which are parallel to the tubes (3), form an angle with the horizontal (14). The aforementioned fluid-through openings are conveniently located at the lower edge of the baffle plate (11), which is connected to the jacket (2), i.e. to the left of the drawing.

The positioning of the baffles (11) also has the additional advantage that the liquid condensing on the surface of the tubes (3) does not run down the lower tubes (3), but is held by the baffle (11) and its edges, flows through the openings (not shown) to the bottom of the cylindrical shell (2). This also improves the heat transfer coefficient as the thickness of the liquid film impeding the heat transfer on the tubes (3) is reduced.

Claims (2)

A lying condenser for liquefying vapors of refrigeration equipment having a jacketed and receiving receptacle for vapors to be liquefied and a bundle of conduits for condensing refrigerant therein, characterized in that the vapor space (12) is connected to at least one 11) divides into passageways (a, b, c, d), the flow cross-section of the passageways (a, b, c, d) decreasing per passageway. A capacitor according to claim 1, characterized in that the baffle plate (11) parallel to the tubes (3) has an angle transverse to the tubes (3) and that the baffle plate (11) is liquid-permeable at the lower edge of the jacket (2). has an opening.