RU2443616C2 - Method of heating and discharge of viscous and congealed products from container and device to this end - Google Patents

Abstract

FIELD: transport, distribution of fluids.

SUBSTANCE: set of invention relates to method of heating and discharge of viscous and congealed products from container and device to this end. Proposed method consists in extracting cold product from container bottom, heating said product in heat exchanger and feeding heated product to several points of said container on of which is located at inlet of channel for extraction of cold product into heating system, feeding heated air into said point at flow rate that allows required fluidity for pumping it in circulation circuit. Note here that said flow rate is set depending upon pump inlet pressure or product temperature upstream of heat exchanger, while rest heated product is fed when all product in said container is heated. Now, heating I s cutoff and all product is drained from container. In heating, product extracted from container is partially discharged when heated product layer thickness above cold product is sufficient for heating product residues on container walls. Invention covers also device to this end.

EFFECT: reduced time of heating and draining.

6 cl, 1 dwg

Description

The group of inventions relates to the unloading of highly viscous and highly hardening products (petroleum products, molasses, fats, etc.) from containers for storage and transportation.

The closest in technical essence to the present invention is a method of heating and draining highly viscous products from a container, in which a cold product is taken from the bottom of the tank, heated in an external heat exchanger and the heated product is returned in a certain ratio of costs to two places in the tank, one of which is located on the entrance to the channel for selection of cold product from the tank into the heating system, the heated product is supplied to this place at a flow rate that provides the necessary fluidity of the cold product for the circulating circuits, which are set by the pressure at the pump inlet or by the temperature of the product in front of the heat exchanger, the remaining preheated product is fed to the surface of the product in the tank, at the moment when the whole product in the tank is heated, the circulation heating is stopped and the product is drained from the tank (see RF patent No. 2204514, IPC B65D 88/74 // B65G 69/20 // B67D 5/04, 2002).

It is also known a device for heating and draining highly viscous products from a container, containing a suction pipe connected in series, a starting container filled with a preheated product, a pump, a heat exchanger with a pipe for supplying a coolant, a pressure pipe having two parallel sections in which control valves are installed, at this suction pipe is connected to the bottom of the tank, while one of the sections of the pressure pipe delivers the hot product directly at the entrance to the suction pipe, another to the surface of the product in the tank. The control elements are controlled by the electronic system according to the values of the product pressure sensor at the inlet to the pump and the product temperature sensor at the inlet to the heat exchanger so that the ratio of the parts to be separated ensures that the pump operates without cavitation when the hot product is fed into the suction pipe in a minimum volume (see there same).

However, the known method of heating and draining highly viscous products and a device for its implementation do not fully solve the problem of heating and draining highly chilled products having a high viscosity and high pour point.

The objective of the invention was to reduce the time of heating and draining of highly viscous products having a high pour point, such as cold fuel oil.

The problem is solved by the method of heating and draining highly viscous products from the tank, which consists in selecting a cold product from the bottom of the tank, heating the product in a heat exchanger and supplying the heated product to several places in the tank, one of which is at the inlet to the cold product withdrawal channel from the tank to the system heating, the supply of the heated product to the indicated location of the tank is carried out with a flow rate that provides the necessary fluidity of the cold product for pumping it along the circulation circuit, and The specified flow rate is set depending on the pressure at the inlet to the pump or on the temperature of the product in front of the heat exchanger, and the rest of the heated product is supplied to the remaining places of the tank, remote from the entrance to the cold product withdrawal channel from the tank, at the time when the whole product it is heated in the container, the heating is stopped and the entire product is drained from the container, while according to the invention, during the heating process, a partial discharge of the product taken from the container, which begins when the thickness is the ina layer of the hot product over the cold in the tank is sufficient to heat the product residues on the walls of the tank in the process of lowering the level in it.

In addition, partial draining of the product is stopped before the level of the product in the tank drops to the minimum level at which the erosion of bottom residues by flooded jets of the heated product is ensured.

In addition, partial discharge is carried out with a flow rate that ensures temperature and pressure in the product stream from the tank, not leading to disruption of the pump.

The task is also solved by a device for heating and draining highly viscous products from the tank, containing a suction pipe for removing cold product from the tank, a starting tank filled with a preheated product, a pump, a heat exchanger with a pipe for supplying coolant, a pressure pipe with two parallel sections in which the control valves are installed, while the suction pipe is connected to the bottom of the tank, the output of one of the sections on The pipeline is intended for flooding in the product and is located at a distance from the inlet to the suction pipe, and the outlet of the second section of the pressure pipe is in close proximity to the inlet to the suction pipe, the control valve actuators are connected to a control system configured to control the control valves by a signal from pressure sensor at the inlet to the pump or from the temperature sensor anywhere on the cold product removal line from the tank to the heat exchanger, moreover, with line connected to the valve outlet for discharging product from the container, the inventive control system is arranged to enable the valve actuator to drain by the temperature sensor signal, set in the container at a level ensuring the temperature control of the heated product layer sufficient to melt the cold product.

In addition, the control system is configured to turn off the valve actuator for discharge by a signal from a level sensor installed in the tank at a level corresponding to the level of the product surface, sufficient for erosion of bottom residues by flooded jets of heated product.

In addition, the valve actuator for draining the product from the tank is connected to the control system with the ability to control the valve for draining according to the signals of the temperature and pressure sensors at the pump inlet.

A feature of the proposed group of inventions is that part of the product taken from the tank is poured into the external storage tank of the product during the circulation heating.

The technical result of the proposed method and device is to reduce the time of heating and draining, as well as saving heat that goes to warm up the product. This effect occurs due to the fact that in order to obtain sufficient fluidity of the product for draining the product from the tank, it is necessary to heat it to a temperature close to that which is provided at the inlet to the circulation heating circuit. This temperature of the product is ensured by mixing the hot product, heated in the heat exchanger, with cold, taken from the tank. Therefore, the temperature of the hot product fed into the tank should be higher than the required temperature of the mixture taken into the circulation system. Moreover, the higher the temperature of the hot product, the greater the consumption of the cold product taken from the tank may be, therefore, the faster the cold product will be replaced in the tank by a heated one, but to a higher temperature. Since the processing time of the tank is the main commercial factor, they try to heat the product in the circulation circuit to the maximum allowable temperature. As a result, faster heating is ensured due to the large expenditures of thermal energy, which ultimately is spent on overheating the entire product, drained after heating the entire tank. If the product is partially drained from the tank at a lower temperature, then the average temperature of the entire drained product will be lower, therefore, the heat consumption for heating the tank will be lower and the heating time will be shorter without increasing the heat capacity. In addition, due to the discharge of a significant part of the product during the heating process, the total drain time is reduced.

However, the incorrect organization of the discharge during the heating of the product in the tanks can lead to disruption of the circulating heating system or to an unacceptable not drained residue in the tank after the discharge.

If the place of partial discharge of the product is provided before the heat exchanger and the temperature and pressure at the inlet to the heating circuit are controlled in a known manner, then with an increase in the flow of partial discharge, the control system will increase the flow of hot product supplied to the place of selection of the cold product from the tank, while maintaining optimal conditions for the circuit circulation heating. If the partial discharge flow reaches a value at which the control system directs all the hot product to the place where the cold product is taken from the tank, then a further increase in the partial discharge flow can interrupt the circulation heating circuit and the increase in the partial discharge flow should be stopped. This will be the maximum allowable partial discharge flow rate, practically without supplying hot product to the tank along the external circulation circuit. Therefore, if a partial drain at such a flow rate is made from the very beginning of the circulation until the tank is completely empty, then with a minimum warm-up and drain time and a minimum amount of heat expended, the product will be drained only from the middle region of the tank, and a significant amount of non-drained product will remain on the periphery of the tank. For this reason, the partial discharge flow rate should either be such that the hot product continues to flow into the tank along the external circulation circuit to form a layer of hot product over the cold product in the tank to melt the cold product on the inner walls of the tank during the level reduction process. With the formation of a sufficient layer of hot product in the tank, the partial discharge rate can be increased to a maximum. In any case, partial discharge of the product from the container should stop when the level of the product in the container does not reach the level of formation of a funnel at the entrance to the drain outlet. In addition, the termination of partial discharge at a certain level of product in the tank is necessary to ensure the safe erosion of bottom residues by flooded jets.

The essence of the device implementing the proposed method is illustrated in the drawing, which shows a schematic diagram of the device.

A device for heating and draining highly viscous products from a container contains a suction pipe 1 connected through a lower discharge pipe 2 to a container 3 with a product, for example, fuel oil. The suction pipe 1 is connected to the starting tank 4 through the valve 5 and then to the inlet of the pump 8 through the valve 7. The starting tank 4 is connected to the inlet of the pump 8 by a pipeline with the valve 6 so that the connection point of the pipeline from the starting tank 4 to the pump 8 inlet valve 7.

This connection scheme allows you to work in two modes:

- mode with connected starting capacity 4 - valve 5 and valve 6 are open, valve 7 is closed, while the product from the tank 3 through the suction pipe 1 enters the starting tank 4, and from it to the pump 8;

- mode with the start tank 4 turned off - valve 7 is open, valve 5 and valve 6 are closed, while the product from the tank 3 through the suction pipe 1 enters the pump 8, bypassing the start tank 4.

The mode with the connected starting capacity 4 is used in the starting mode of the pump 8 to collect air from unfilled pipelines in the upper part of the starting capacity 4 and to prevent them from entering the pump 8 (air separation).

After air separation, a transition to the operation mode with the disconnected starting capacity is carried out.

The output of the pump 8 is connected to the heat exchanger 9. The heat exchanger 9 has a pipeline for supplying a heat carrier, for example water vapor, in which a control valve 11 is installed, which is controlled by an electronic control system 27 along line 35 by the signal of the temperature sensor 13 installed in the pressure pipe at the outlet of the heat exchanger 9.

The pressure pipe 12 has two parallel sections 14 and 15, on each of which are mounted controlled control valves 16 and 17, designed to separate the hot product from the heat exchanger 9 into flows entering sections 14 and 15.

Section 15 is introduced through the upper neck 18 of the tank 3 into the upper part of the tank 3 and is equipped with two hinged nozzles 19 and 20 with nozzles designed to supply jets of hot product from the heat exchanger 9 on the bottom of the tank 3 in the direction of the ends of the tank and the tank drain valve.

Section 14 through the lower discharge pipe 2 is introduced into the bottom of the tank 3 with the product, while its end part 21 located in the bottom of the tank 3 is equipped with nozzles 22 and 23, which are directed towards the inlet section of the suction pipe 1 and are intended to supply part hot product from the heat exchanger 7 to the inlet section of the suction pipe 1.

The device is equipped with an electronic operation control system 27, the input 31 of which is connected to the output of the product pressure sensor 29 at the output of the pump 8, and the input 30 is connected to the output of the pressure sensor 28 in front of the pump 8. The outputs 32 and 33 of the control system 27 are connected to the actuators of the controlled control valves 16 and 17, respectively.

A temperature sensor 25, connected to the electronic system 27 by an input 36, and a level sensor 26, connected to the electronic system 27 by an input 37, are introduced into the container 3 through the upper neck 18.

The discharge of the product from the tank 3 is provided by the pump 8 to the receiving manifold (not shown in the drawing) through a pipeline with a control valve 10, which is connected to the control system 27 of the output 34.

Partial discharge of the product from the tank 3 is carried out by the pump 8 through the valve 10 under the following conditions:

- received a signal from the temperature sensor 25 - the formation of a layer of hot product of sufficient height from the initial level 13 of the product in the tank 3;

- there was no signal from the level sensor 26 about the minimum decrease in the level of the product in the tank 3;

- differential pressure 29 at the outlet of the pump 8 and pressure 28 at the inlet of the pump 8 is not lower than the allowable for the operation of the pump 8 without cavitation.

The temperature and pressure at the inlet to the circulation heating circuit depend on the flow rate of the partial drain. The higher the partial discharge rate, the lower the temperature and pressure at the inlet to the pump 8, which can lead to disruption of the pump and disruption of the entire circulation heating circuit.

The partial discharge rate is controlled by valve 10 as follows.

- If the temperature or pressure at the inlet to the pump 8 is lower than the specified allowable values for the normal operation of the pump 8, then the valve 10 partially closes.

- If the temperature or pressure at the inlet to the pump is higher than the specified allowable values for the normal operation of pump 8, then valve 10 partially opens.

When the level in the tank 3 decreases until the level sensor 26 is triggered, the partial discharge stops and the bottom sediments in the tank 3 are washed out.

At the end of the erosion, the product is completely drained from the tank 3 by the pump 8 through the valve 10.

Claims (6)

1. The method of heating and draining highly viscous products from the tank, which consists in the selection of cold product from the bottom of the tank, heating the product in a heat exchanger and supplying the heated product to several places in the tank, one of which is at the entrance to the cold product withdrawal channel from the tank to the heating system , the supply of the heated product to the specified location of the tank is carried out with a flow rate that provides the necessary fluidity of the cold product to be pumped by the pump along the circulation circuit, and the value of the specified flow rate depending on the pressure at the inlet to the pump or on the temperature of the product in front of the heat exchanger, and the rest of the container, remote from the inlet to the selection channel of the cold product from the tank, feed the rest of the heated product when the entire product in the tank is heated stop heating and drain the entire product from the tank, characterized in that during the heating process, a partial discharge of the product taken from the tank is carried out, which is started when the layer thickness of the hot product is cold in the container is sufficient to heat the product is still on the vessel wall in the process of reducing it. 2. The method according to claim 1, characterized in that the partial discharge of the product is stopped before the product level in the tank drops to the minimum level at which the erosion of bottom residues by flooded jets of the heated product is ensured. 3. The method according to claim 1, characterized in that the partial discharge of the product with a flow rate that provides temperature and pressure in the product stream from the tank, not leading to disruption of the pump. 4. A device for heating and draining highly viscous products from the tank, containing a suction pipe for removing cold product from the tank, a starting tank filled with a preheated product, a pump, a heat exchanger with a pipe for supplying coolant, a pressure pipe with two parallel sections, in which are equipped with control valves, while the suction pipe is connected to the bottom of the tank, the outlet of one of the sections of the pressure pipe is intended For flooding in the product and is located at a distance from the inlet to the suction pipe, and the outlet of the second section of the pressure pipe is in close proximity to the inlet to the suction pipe, the control valve actuators are connected to a control system configured to control the control valves by a signal from a pressure sensor to at the inlet to the pump or from the temperature sensor anywhere on the cold product discharge line from the tank to the heat exchanger, with a branch connected to the specified line with a valve for For draining the product from the tank, characterized in that the control system is configured to turn on the valve actuator for draining by the signal of a temperature sensor installed in the tank at a level that provides temperature control of the heated product layer sufficient to melt the cold product. 5. The device according to claim 4, characterized in that the control system is configured to turn off the valve actuator for draining by a signal from a level sensor installed in the tank at a level corresponding to the level of the product surface, sufficient for erosion of bottom residues by flooded jets of a heated product. 6. The device according to claim 4, characterized in that the valve actuator for draining the product from the tank is connected to a control system with the ability to control the valve for draining according to the signals of the temperature and pressure sensors at the pump inlet.