PL197643B1 - Apparatus for transferring heat in direction opposite to that of natural convection - Google Patents

Abstract

Device for spontaneous heat transfer towards opposite to natural convection made in the form of circulation closed, partially filled with liquid, containing lifting and falling branches, radiator, cooler, intermediate channel and a fluid closure connecting the lift to the drop portion circuit, having an expansion vessel with warm working medium and an expansion vessel with a cold working medium, wherein There is an entrance in the lower part of the warm expansion vessel the drop branch, and above is a liquid seal consisting of a dosing vessel and a culvert pipe and an outlet U-shaped intermediate channel, and in the collection vessel when cold, in the lower part there is an entrance to the intermediate channel, and above the exit of the lifting branch and the exit of the lead-through pipe the liquid closure and the entry of the sink pipe which has the other end is attached to a drain vessel, preferably all of them circuit elements having detachable joints are arranged in tanks filled with a liquid sealing agent working; having a subcarrier exit located above drop branch entry level and the top edge of the vessel the dosing unit and the output of the intermediate channel are situated between the level of the exit of the subcarrier and the entry of the branch and the exit of the intermediate channel is situated above the top of the dosing vessel and the pipe entrance the catchment area is situated between the exit of the subcarrier and the output level of the intermediate channel according to Patent No. 195 490, characterized in that to the top of the sink pipe (15) between the cold vessel (4) and the drain vessel (16) are attached a container (22) for collecting gases.

Description

Description of the invention

The subject of the invention is a device for transferring heat in the opposite direction to natural convection, which can be used in various fields of the economy, where there is a need to heat lower-lying objects, such as the ground under the road, under the airport runway or in inspection frames, as well as to transfer heat from the solar collector to the tank downstairs, for heating liquid combustible gas in underground storage, for mixing water in lakes and ponds, etc.

According to patent no. 195 490, one of the variants of the device for spontaneous heat transfer in the opposite direction to natural convection has a collection vessel with a hot working medium and an expansion vessel with a cold working medium, and the intermediate channel is U-shaped. part is the entrance of the drop branch, and above it is a liquid seal consisting of a dosing vessel and a transfer pipe, as well as the exit of the intermediate channel. In the collection vessel with the cold working medium, in the lower part there is the inlet of the intermediate channel, and above it is the outlet of the lifting branch, as well as the outlet of the liquid closure passage pipe and the inlet of the sink pipe with the other end connected to the catchment vessel. All elements of the circuit with detachable joints are placed in tanks filled with a sealing liquid working medium.

In this device, the output of the subcarrier is located above the entry level of the drop branch and the upper edge of the dosing vessel and the exit of the intermediate channel are located between the exit level of the subcarrier and the entry of the drop branch, and the exit of the intermediate channel is located above the top edge of the dosing vessel. The entry of the catch pipe is located between the exit of the subcarrier branch and the exit level of the intermediate channel.

According to the invention, a container for collecting gases is attached to the upper part of the sink between the cold vessel and the sink.

The device according to the invention, through the use of a gas container, allows the self-setting and permanent maintenance of a negative pressure in the device without the need to remove the air that has entered the device due to leakage in the circulation.

The subject of the invention will be explained in more detail in an embodiment in the drawing showing the device in a general diagram.

The device according to the invention has branches: dropping - warm 1 and lifting - cold 2, in the upper parts of which there are respectively located a warm expansion vessel 3 and a cold expansion vessel 4. The device also has an intermediate channel 5 made in the shape of the letter U, and in the warm expansion vessel 3, there is a liquid closure, which consists of a dosing vessel 6 and a through-pipe 7. The heat source 8 heats the warm expansion vessel 3 and the cooler 9 is located in the lower part of the circuit. In the warm expansion vessel 3 there is the input 10 of the rainfall branch 1, the output 12 of the intermediate channel 5 and the liquid closure 6 and the inlet part of the culvert pipe 7. In the cold collecting vessel 4 there is the inlet 13 of the intermediate channel 5, the outlet 11 of the lifting branch 2, the outlet 14 of the culvert 7 and the inlet 17 of the drain pipe 15. The drain pipe 15 is connected with its other end. it is to a catch vessel 16 below. This provides for automatic drainage of excess liquid that may be supplied to the device at initial filling or during operation of the device. Detachable circuit connections are placed in tanks 18 filled with a sealing liquid working medium 21. Inside the device there is a liquid working medium 19 and its vapor 20. A container 22 for collecting gases is attached to the upper part of the sink pipe 15 between the cold vessel 4 and the drain vessel 16. A valve and a siphon 23 or a flexible wall are mounted at the outlet of the catch pipe 15 placed in the catch vessel 16.

During operation of the device in the warm side of the circuit, the liquid level cyclically varies from the edge of the dosing vessel 6 downwards and back again, the lower level being determined by how the liquid closure is adjusted.

The level of the liquid working medium in the cold side of the circuit fluctuates with the fluctuation of the liquid working medium in the warm side of the circuit, but here the level should not fall below the level of the output 12 of the intermediate channel 5 to be able to sink the liquid by gravity into the warm expansion vessel 3 through the channel intermediate 5.

The inlet 10 to the drop branch 1 is placed in the lower part of the warm expansion vessel 3, and the inlet 13 to the intermediate channel is located in the lower part of the cold expansion vessel 4. This ensures the correct direction of the flow of warm liquid in the downstream branch and down to the cooler. 9 and the cold liquid also down through the intermediate channel 5 to the upper warm side of the circuit.

The exit 11 from the lifting branch 2 to the cold collecting vessel 4 is located higher from the entry level 10 to the dropping branch 1. The upper edge of the dosing vessel 6 and the exit 12 from the intermediate channel 5 to the warm collecting vessel 3 are located between the exit 11 from the lifting branch 2 into the cold collection vessel 4 and the entry level 10 into the drop branch 1, the exit 12 from the intermediate channel 5 being higher than the upper edge of the dosing vessel 6.

Such a design creates conditions for the cyclical fluctuation of the hot liquid from the level of the edge of the dosing vessel 6 downwards and the cold liquid from the level of the exit from the intermediate channel 5 upwards, i.e. above the level of the edge of the dosing vessel 6. Thus, a one-way closed-circuit liquid flow is ensured, and possibility of filling the dosing vessel 6.

Realization of these possibilities is achieved under the condition of maintaining the appropriate limits of fluctuating levels of hot and cold liquid and on condition of proper opening of the liquid closure. These conditions are as follows.

The device is filled with the liquid working medium 19 in such an amount as to fill the expansion vessel 3 with the dropping 1 and lifting branches 2 to the level of the upper edge of the dosing vessel 6, during operation it is the maximum liquid level in the warm expansion vessel 3 and, at the same time, the cold expansion vessel 4 with an intermediate channel 5 to the level of the exit 12 from the intermediate channel 5. This is guaranteed by the gravity sink of excess liquid from the cold expansion vessel 4 to the warm expansion vessel 3 and also to the dosing vessel 6.

The device is supplied with the liquid working medium 19 in such an amount that it does not exceed the upper edge of the dosing vessel 6 in the collection vessel 13 and, at the same time, in the cold expansion vessel 4 the level of the output 11 from the lifting branch 2. Any further excess of liquid may cause an overrun during operation. level of the exit 11 from the lifting branch 2, and thus may lead to an undesirable return flow of the cold working medium 19 through both branches of the circuit and the cooler 9, which does not correspond to the purpose of the device.

The liquid closure is adjusted in such a way that the pressure difference in the warm 3 and cold 4 collection vessels, at which the liquid closure opens, raises the liquid from the upper edge of the dosing vessel 6 to the level of exit 11 from the lifting branch 2. This ensures that the liquid is pumped through to the cold expansion vessel 4. Together with this, the pressure difference at which the liquid seal opens is not greater than that which will cause, during operation in the cold expansion vessel 4, the liquid working medium to exceed the outlet level 11 of the subcarrier 2. This prevents the return flow through lifting branch 2 and dropping branch 1 of the circulation circuit.

The inlet 17 from the cold collection vessel 4 to the catch pipe 15 is located below the exit 11 of the subcarrier 2 but above the level of the exit 12 of the intermediate channel 5. This ensures that the sink does not expel too much liquid from the circulation circuit and prevents accumulation of liquid above exit level 11 from the lifting branch 2.

The pressure difference in the warm 3 and cold 4 expansion vessels, at which the liquid seal opens, is not greater than that which, during operation, will cause the liquid to be squeezed into the expansion vessel 4 above the level of the entry 17 into the drain pipe 15.

The intermediate channel 5 is U-shaped. The depth of the channel from its exit 12 to the lowest point of the channel is not less than such that when the liquid seal is opened under the action of excess pressure in the warm expansion vessel 3, no steam of the working medium passes through the intermediate channel 5. twenty.

The detachable circuit connections can be placed in the tanks 18 filled with the sealing fluid 21 in such a way that the connections are positioned below the level of the sealing fluid 21 in order to replace the undesirable air inflow into the supply in the event of negative pressure, e.g. for water at temperatures below 100 ° C. of the working medium itself, which does not hinder the processes of condensation of the vapor in the collecting vessel 4. In addition, the excess liquid formed in the device can be discharged from the circuit, for example via a drain pipe 15.

A container 22 for collecting gases is attached to the upper part of the sink pipe 15 between the cold vessel 4 and the sink 16. This allows for a more permanent vacuum in the device without pumping out the air that has entered the device as solution 4

Released in liquid or due to leakage. The container 16 into which the excess liquid is poured has a siphon or a flexible - flexible wall, and the height of the sink pipe 15 is sufficient to create a negative pressure in the upper part of the circuit under the effect of the weight of the column of liquid in the pipe.

The catch vessel 16 may or may not be insulated from the environment, in which case the vessel should be suitably located to balance the atmospheric pressure, the pressure inside the apparatus and the pressure exerted by the liquid column in the catch pipe 15. For those liquids whose saturation pressure at operating temperatures is sub-atmospheric, for example for water at temperatures below 100 ° C, this makes it possible to spontaneously maintain a negative pressure in the device.

The valve 23 allows the device to be completely filled with liquid, and when the valve 23 is opened, a negative pressure will spontaneously create in the device. Consequently, excess liquid will drain into the drain pan 16.

Claims (1)

Device for spontaneous heat transfer in the opposite direction to natural convection, made in the form of a closed circuit, partially filled with liquid, including a lifting and dropping branch, a radiator, a cooler, an intermediate channel and a liquid closure connecting the sub-beam with the downward part of the cycle, having a collection vessel with a warm working medium and an expansion vessel with a cold working medium, in the lower part of the warm expansion vessel there is an inlet of the rainfall branch, and above there is a liquid closure consisting of a dosing vessel and a transfer pipe, and an outlet of the intermediate U-channel, and in the cold expansion vessel in in the lower part there is an inlet of the intermediate channel, and above the outlet of the sub-lifting branch, as well as the outlet of the liquid closure passage pipe and the inlet of the drain pipe, which at the other end is connected to the catch vessel, preferably all elements of the circuit with detachable connections are placed in the tank tines filled with a sealing liquid working medium; having an exit of the subcarrier located above the entry level of the downward branch, and the upper edge of the dosing vessel and the exit of the intermediate channel are located between the exit level of the subcarrier and the entry of the dropping branch, while the exit of the intermediate channel is above the upper edge of the dosing vessel and the entry of the sink pipe is located between the exit of the subcarrier branch and the exit level of the intermediate channel according to Patent No. 195 490, characterized in that a gas collection container (22) is attached to the top of the sink pipe (15) between the cold vessel (4) and the catch vessel (16).