This application claims priority to Netherlands Patent Application No. 2009749 filed on Nov. 2, 2012 in the Netherlands Intellectual Property Office, the disclosure of which is hereby incorporated by reference in its entirety.
1. Field of the Invention
The present invention relates to a tank container comprising a container for a liquid to be stored or transported, a pipe circuit comprising a heat transfer circuit part mounted to the wall of the container, which pipe circuit is filled with glycol, a storage vessel connected to the pipe circuit for holding an amount of glycol, a heating device designed for selectively heating the glycol in the pipe circuit, and a pump in the pipe circuit for circulating the glycol.
2. Description of Related Art
As a rule, the container is a substantially cylindrical tank, for example having a diameter of about 2.5 meters, a length of about 6 meters and a capacity of about 26,000 liters, which tank is often mounted in a block-shaped frame having an ISO 20 feet dimension.
Usually, such heating systems for tank containers use a cooling medium consisting of a mixture of glycol and water mixture in a proportion of about 1:1, the maximum temperature of the mixture being 100° C. If a cooling medium temperature of between 100° C. and 140° C. is required, the cooling medium will have to consist of at least substantially 100% pure glycol, because the boiling point of pure glycol is well above 150° C. The drawback of pure glycol is that it has a high viscosity at lower temperatures (below 25° C.), so that pumping it is difficult and gradually becomes impossible. This is problematic especially if the heating system has been off for some time and circulation of the cooling medium must be started.
The object of the invention is to solve this problem.
According to the invention, a second heating device is to that end provided in or around the storage vessel, which heating device is designed for maintaining the temperature of the glycol in the storage vessel at at least 25° C., preferably at least 35° C. In this way the glycol can be brought to a temperature at which the glycol can be circulated independently of the ambient temperature.
The pump is preferably designed for circulating the glycol only when the temperature of the glycol in the storage vessel exceeds a predetermined limiting value, preferably at least 25° C., more preferably at least 35° C. To that end a thermostat fitted with a sensor is preferably mounted in or to the storage vessel, which thermostat is capable of turning the pump or on and off. The pump is preferably incorporated in the pipe circuit (directly) after the storage vessel and before the aforesaid heating device.
Preferably, a thermostat valve provided with a bypass line is incorporated in the pipe circuit after the aforesaid heating device and before the heat transfer circuit part, which thermostat valve is designed for causing at least part of the glycol to flow back to the storage vessel if the temperature of the glycol in the pipe circuit before the inlet of the storage vessel is lower than a predetermined limiting value, for example 35° C. or 25° C. This prevents cold glycol flowing back into the storage vessel if the tank container is completely cold, and thus the need to start the heating cycle all over again. If there is a flow in the pipe circuit, the main heating element can remain on. The system will thus reach its desired minimum temperature sooner. In an alternative embodiment, a pressure-controlled valve (for example a spring-loaded valve) provided with a bypass line is installed in the pipe circuit after the first heating device and before the heat transfer circuit part, which valve is designed to cause at least part of the glycol to flow back to the storage vessel when the pressure of the glycol in the pipe circuit exceeds a predetermined limiting value. Too high a viscosity of the glycol at a low temperature will cause the pressure experienced by the pump, for example, to increase. At that point the valve can be opened for causing at least the aforesaid part of the glycol to flow back to the storage vessel so as to be heated.
The second heating device preferably comprises an electrical heating coil in the storage vessel. The second heating device is preferably designed for pulsed heating. This prevents burning of the glycol that is in contact with the heating coils. When pulsed heating by the heating coils is used, the glycol that is in contact with the heating coils will have sufficient time for transferring the heat it has absorbed to the glycol that is present further on.
Preferably, the first heating device likewise comprises an electrical heating element.
With reference to the diagram of
Electrical heating coils 4 are disposed in the glycol vessel 6, by which heating coils the glycol supply, and to a certain extent also the other parts of the system, are pre-heated. As soon as the glycol reaches a temperature of about 40° C., the pump 8 will turn on, causing the glycol to circulate, and the heating element 7 will turn on.
In a preferred embodiment, a thermostat valve 16 is incorporated in a bypass line 18 between the supply line 14 and the discharge line 15, which thermostat valve 16 is connected to a temperature sensor on the discharge line 15, and which is set so that the glycol will be pumped back (in part) to the storage vessel again when the temperature in the discharge line falls below a predetermined temperature, for example about 35° C. This prevents cold glycol flowing back into the storage vessel 6 and thus a complete restart of the heating cycle when the container 2 is completely cold. When there is a flow, the main heating element 7 can remain on, so that the system will soon reach its desired minimum temperature.
Since glycol has a lower heat conduction coefficient than water, pulsed heating is employed with the heating coil in the glycol storage vessel 6 in a preferred embodiment, because otherwise the glycol that is in contact with the heating coils 4 will burn. In the case of pulsed heating by the heating coils 4, the glycol being in contact with the heating coils will have sufficient time for transferring the absorbed heat to the glycol present further on.
Number | Date | Country | Kind |
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2009749 | Nov 2012 | NL | national |
Number | Name | Date | Kind |
---|---|---|---|
4359084 | Geverath et al. | Nov 1982 | A |
20130192684 | Ohkami et al. | Aug 2013 | A1 |
Number | Date | Country |
---|---|---|
202012005624 | Sep 2012 | DE |
0256292 | Feb 1988 | EP |
101267110 | May 2013 | KR |
2004667 | Nov 2011 | NL |
2011129306 | Oct 2011 | WO |
Number | Date | Country | |
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20140124497 A1 | May 2014 | US |