DE451289C - Condenser for refrigeration systems - Google Patents

Description

Condenser for refrigeration systems. The invention relates to a condenser for refrigeration systems and is based on the following considerations: In the case of a condenser, one can distinguish three, albeit not sharply delimited, zones: the desuperheating zone, the actual liquefaction zone and the post-cooling zone. In the two first-mentioned zones, the speed of the refrigerant, which is still gaseous, is very high, which is why it is necessary to ensure that the cooling liquid brushing the heat exchange walls is changed quickly. Accordingly, for the Ent. heating and liquefaction zone the irrigation with a weak, but fast flowing stream of cooling liquid or an equivalent cooling method in place. In the post-cooling zone, on the other hand, the speed of the already completely liquefied refrigerant is many times lower, so that the simple immersion process with a strong but slow flow can be used here with advantage.

The subject matter of the invention exists in accordance with these relationships in a condenser, which is in the desuperheating and actual condensing zone designed as a sprinkler, in the post-cooling zone, on the other hand, as an immersion condenser is. The disadvantage, which at first glance appears to be such, that with a such a measure according to the invention at the expense of equity the production of several different cooling devices in one and the same Heat exchangers need to be put together, as shown in the illustration Ausfühiungsbeispieles is shown through particularly advantageous arrangement and use of space be balanced.

In the casing tube g, which is closed off by the end wall d, a number (approximately y) tubes a, b, c etc. are arranged in a known manner, which pass through the end wall d in an open manner. This tube structure g, a, b, c etc. continues below as a column of appropriate length, the lower end (not shown) being designed in a similar manner in the upper end with a front closure and continuous inner tubes. The space rt remaining between the jacket g and the inner tubes a, b, c etc. now serves as a desiccant and liquefaction zone. The refrigerant is introduced into the room below, for example, and spreads in this in a known manner. The external irrigation of the jacket q and internal irrigation of the tubes a, b, c etc. cause the liquefaction, and the liquid collects on the lower floor of the room up to a certain height which can be regulated by known means. She can. can be used as a desuperheater by introducing the gaseous cold stone at the bottom and forcing it in a known manner to flow through the already liquefied refrigerant in the form of bubbles. The path of the condensate continues through the pipe f into the after-cooling coil s, to finally exit at g.

The cooling liquid is introduced through the pipe la into the immersion space A, flows in countercurrent around the cooling coil s, then passes over the inner edge e, which is lower than the outer edge o, into the space .B, which is delimited at the bottom by the end walld. Here the coolant is distributed over the inner tubes a, b, c etc., sprinkling them from the inside. The outer jacket c / is sprinkled in a parallel branching of the coolant through the annular gap, entering the annular space C at h. The openingi is usually closed and serves only as an outlet after the end of operations. The after-heat sink is fastened by means of the stud bolts t. The inserts v are used in a known manner for ventilation and better distribution of the trickle liquid on the inner walls of the pipe, etc. The seal m can also be omitted, whereby under simultaneous omission of the distributor space C the external sprinkling of the jacket g also happens directly from the space B.

A liquefier has already been proposed in which also a double cylindrical body is used, in which of the refrigerant through which the annulus is flooded, an already liquefied refrigerant flows through it Pipe coil is mounted, and in which the inner cylindrical space is used as a desuperheating and liquefaction zone is used. In this condenser, however, both the coil as well as the desuperheating and liquefaction space in common with the annulus cooling medium flowing through, so that the forming the starting point of the invention advantageous adaptation of the speed of the refrigerant to the state of tightness of the refrigerant does not take place.

Claims (1)

PATRNTANSYRÜCHR: i. Condenser for refrigeration systems, characterized in that it is designed as a sprinkler in the de-heating and liquefaction zone and as an immersed condenser in the post-cooling zone. z. Combined sprinkling and immersion condenser according to claim i, in which the immersion condenser forming the post-cooling zone consists of an immersion tank with an annular cross-section with a pipe coil stored in it, and the cylindrical space remaining in the interior of the annular immersion tank is used to accommodate the desuperheating and liquefaction space, = characterized in that the outer wall (o) of the annular container is higher than its inner wall (e), the space enclosed by the inner wall (e) with its lower part the upper head end of the sprinkling body (g, a, b, c, d ) while its upper section (B) serves as a distribution space for the sprinkling liquid overflowing the inner wall (e). 3. Condenser according to claim a, characterized in that the arranged at the upper head end of the sprinkler body designed as a tube bundle element has a special trough (C, r) for the outer jacket (g) of the tube bundle sprinkler, in which the cooling liquid in parallel branch to the is introduced into the immersion vessel guided cooling liquid flow.