Heat exchanger with integral internal temperature sensor

Details Heat exchanger with integral internal temperature sensor Heat exchanger with integral internal temperature sensor

2001-12-06

2004-11-16

McKinnon, Terrell (Department: 3743)

Heat exchange

With timer, programmer, time delay, or condition responsive...

Temperature responsive or control

C165S231000, C062S139000

Reexamination Certificate

active

06817408

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates generally to a heat exchanger and more particularly to a heat exchanger having a temperature sensor for monitoring the temperature of the coolant passing in contact with the heat transfer surfaces of the heat exchanger.
BACKGROUND OF THE INVENTION
Many chemical reactions require close control of the reaction temperature. For example, in the pharmaceutical industry, it is not uncommon to use the batch method to prepare certain pharmaceuticals in a reactor vessel wherein the process temperature is as low as −150° F. (−100° C.) or even colder and down to temperatures as cold as −184° F. (−120° C.). Moreover, it is desirable to maintain the temperature of the reactor vessel within a narrow range and preferably at the lower end of the range so as to prolong the reaction time. Extending the batch reaction time provides a greater control over the reaction and an improvement in quality of the product. For example, if the acceptable range of the process temperature is (−100° F. to −150° F. −73° C. to −100° C.), each 18° F. (10° C.) decrease of the reaction temperature within this range can double the reaction time. Accordingly, a process temperature at the lower end of this range and as low as possible is preferred. Conversely, an increase of the temperature within the operating range speeds the reaction, decreases the quality of the materials produced and endangers the control over the reaction. There even is a danger of a runaway reaction should the temperature rise above the preferred range.
In order to maintain the proper operating temperature, the reactor vessel usually is jacketed. A low-temperature heat transfer fluid circulating through the jacket removes the exothermic heat of the reaction and heat gained from the surrounding environment. The heat transfer fluid in turn is circulated through an external heat exchanger in order to reject the heat gained during passage about the reactor vessel. Whereas a low-temperature heat transfer fluid is used for cooling the reactor vessel, a cryogen such as liquid nitrogen is used as the cooling fluid in the heat exchanger to remove heat from the low-temperature fluid heat transfer fluid.
Conventional practice is to measure the average or “bulk” temperature of the heat transfer fluid as it exits the heat exchanger. In response to this measure, adjustments are made by changing either the flow rate of the heat transfer fluid through the heat exchanger or by changing the flow rate of the cryogen. Relying upon the average outlet temperature of the heat transfer fluid (the “cooled fluid”) to initiate flow changes has not been entirely satisfactory. This is because the temperature that is measured is merely the average temperature of the cooled fluid leaving the external heat exchanger and is not necessarily a correct indication of the cooling condition at the interface between the cooled fluid and the cryogen.
It should be appreciated that the temperature of the heat transfer surface in contact with the cooled fluid is actually below the freezing point of the cooled fluid, especially where a cryogen such as liquid nitrogen is used as the medium to remove heat from the cooled fluid. Accordingly, it is important to the operation of the heat exchanger that conditions be maintained so as to avoid the freezing of the cooled fluid onto the heat transfer surface. This is because there is a marked difference in the temperature of the heat transfer surface and the operation of the heat exchanger when the cooled fluid freezes onto the heat transfer surface.
For example, once the cooled fluid begins to freeze onto the heat transfer surface, there is a dramatic temperature change, due in part to the insulation properties of the ice collecting on the heat transfer surface. The build up of ice on the heat exchange surfaces also may restrict flow passages through the heat exchanger. The restriction of the flow passages and the insulation provided by the build up of an ice layer act to compromise the thermal efficiency of the heat exchanger. However, the decrease in the heat exchange capability may not be immediately recognized because the average or bulk temperature of the cooled fluid at the outlet to the heat exchanger still may be within acceptable limits. So long as the temperature sensor sees that the cooled fluid leaving the heat exchanger is at an acceptable level, no corrective measures are taken. Accordingly, relying on the bulk temperature of the cooled fluid delays the taking of corrective action.
Each one of various factors plays a roll in determining whether the cooled fluid begins to freeze onto the heat transfer surface. Among these are the geometry of the heat exchanger and the physical properties of the cooled fluid. Other factors affecting the onset of freezing include the velocity of the cooled fluid across the heat transfer surface, the turbulence of the boundary layer at the heat transfer surface and the thermal diffusivity of the cooled fluid. Also, a heat transfer fluid made of a single compound such as methanol may freeze quickly once a certain temperature is reached. Other fluids comprising a mixture of different organic isomers having different freezing points may not be compromised as quickly since one or more components of the mixture may remain fluid even while other components may freeze. Accordingly, in view of the many variables that may have an affect on the onset of freezing, it is difficult to predict whether a given cooled fluid will freeze under a given set of conditions. Once freezing begins, the temperature of the heat transfer surface may very quickly experience a decrease of from 50° to 100° F. (28° to 56° C.) or more and this decrease promotes further rapid freezing.
As noted above, the conventional method of relying on the bulk temperature of the cooled fluid leaving the heat exchanger is not reliable because the bulk temperature can remain within acceptable limits for some time after the onset of freezing. At some time however, a condition termed “runaway freeze-up” may occur, which results in a dramatic loss of heat rejection capability by the heat exchanger. Corrective action after the cooled fluid temperature goes beyond an acceptable limit usually takes the form of decreasing the flow of the cryogen until the ice build up on the coils is removed. Unfortunately during this period the ability of the low temperature heat transfer fluid to remove heat of the reaction from the reactor is compromised. Should the reactor temperature increase beyond acceptable limits, the pharmaceutical produced either is of a poorer quality or must be discarded.
Accordingly, it is an object of the present invention to provide a heat exchange method and apparatus for more accurately monitoring the thermal condition of a fluid being cooled by the heat exchanger.
Another object of the present invention is to provide a heat exchange method and apparatus wherein the thermal condition of a fluid being cooled is measured independently of the fluid itself.
Yet another object of the present invention is to provide a heat exchange method and apparatus wherein the thermal condition of a heat exchange fluid is controlled by monitoring the surface temperature of a heat exchange surface.
A further object of the invention is to provide a heat exchange method and apparatus for controlling the temperature of heat exchange fluid used in cooling a pharmaceutical reactor.
SUMMARY OF THE INVENTION
In accordance with the method of the present invention, a low temperature heat transfer fluid is circulated about a pharmaceutical reactor to remove the exothermic heat of the reaction and maintain the reactor vessel at a substantially constant temperature. The heat transfer fluid in turn is circulated through a heat exchanger where the heat of the reaction picked up by the fluid is released to a cooling fluid. In this respect the heat transfer fluid is circulated through a heat exchange apparatus and into contact with cooling coils within the heat exchanger. A c

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