RU48713U1 - FOOD PRODUCTION PLANT - Google Patents

Abstract

The invention relates to a device for drying feed and can be used for the production of meat and bone meal. The installation comprises a boiler 1, connected to a heat exchanger 2, and a reverse water supply system for cooling the latter, consisting of a series of pipelines of a cooling tower 4, a reverse water tank 6, and a circulation pump 7. The objective of the utility model is to increase the reliability of the installation during winter operation. Unlike the prototype, the recycled water supply system is equipped with three additional pipelines connected by their outlet sections to the recycled water tank, the inlet sections of two of these pipelines are connected to the heat exchanger, the inlet section of one of them connected to the outlet pipe of the heat exchanger, and the inlet section of the other is connected to the inlet pipe of the heat exchanger, an additional pipe that is connected to the inlet pipe of the heat exchanger is equipped with a control valve controlled by a sensor Using the temperature set at the outlet pipe of the heat exchanger, the inlet section of the third additional pipe is connected to the boiler through its pipe for the exit of condensate of heating steam. An additional pipeline connected to the outlet pipe of the heat exchanger provides the possibility of water circulation in the circulating water supply system, bypassing the cooling tower, which is necessary when starting up the unit in winter. The second additional pipeline connected with the inlet pipe of the heat exchanger creates the possibility of water circulation along the additional circuit together with the main one. This ensures a reduction in water flow through the heat exchanger and an increase in the temperature of the water leaving it. The water flow rate is controlled by a valve and maintains a safe water temperature at the inlet to the tower, which increases the reliability of the installation, eliminating freezing of water in the tower at a low outside temperature at the end of the drying cycle. The third additional pipeline connected to the boiler through the pipe for the exit of the condensate of the heating steam, provides this condensate with a feed system for reverse water supply. This reduces the concentration of hardness salts in the water and increases the reliability of the installation.

Description

The invention relates to a device for drying feed and can be used for the production of meat and bone meal.

A known line for the production of meat and bone meal according to the USSR copyright certificate for invention No. 1598958, A 23 N 17/00, containing boilers associated with heat exchangers, and a circulating water supply system for cooling the latter, consisting of a cooling tower and a pump.

The disadvantage is the low reliability of the device in the winter at low outside temperatures, because water may freeze in the tower at the beginning and at the end of the production cycle, when the flow rate of the vapor (juice vapor) from the boiler is small and the temperature of the circulating water at the outlet of the heat exchanger is low.

The cooling tower constantly evaporates the water, and make up for it with tap water containing hardness salts, which increases the hardness of the circulating water. This leads to the subsidence of salts in the circulating water supply system (pump, pipes, cooling tower), which reduces the reliability of the device.

There is also known a device for the production of meat and bone meal according to the Russian patent for utility model No. 36944, A 23 N 17/00, taken as a prototype and containing a boiler connected to a heat exchanger, and a reverse water supply system for cooling the latter, consisting of a cooling tower piping system connected in series, circulating water tank and circulation pump.

However, the reliability of the device is also low at low outdoor temperatures, because water may freeze in the tower at the beginning and at the end of the production cycle, when the vapor flow from the boiler is small and the temperature of the circulating water at the outlet of the heat exchanger is low.

Constant evaporation of water also occurs in the cooling tower, and it is replenished with tap water containing hardness salts, which increases the hardness of the circulating water. This leads to the subsidence of salts in the circulating water supply system (pump, pipes, cooling tower), which reduces the reliability of the device.

The objective of the utility model is to increase the reliability of the installation when working in the winter.

PLANT FOR PRODUCTION OF FEEDS, contains a boiler connected to a heat exchanger, and a reverse water supply system for cooling the latter, consisting of a series of cooling tower pipelines, a reverse water tank, and a circulation pump.

Unlike the prototype, the reverse water supply system is equipped with three additional pipelines connected by their outlet sections to the reverse water tank, the inlet sections of two of these pipelines are connected to the heat exchanger, the inlet section of one of them connected to the outlet pipe of the heat exchanger, and the inlet section of the other is connected to the inlet pipe of the heat exchanger, an additional pipe that is connected to the inlet pipe of the heat exchanger is equipped with a control valve controlled by a sensor com temperature set at the heat exchanger outlet conduit, the input portion of the third additional conduit connected to the boiler through the pipe to its exit of the heating steam condensate.

An additional pipeline connected to the outlet pipe of the heat exchanger provides the possibility of water circulation in the circulating water supply system, bypassing the cooling tower, which is necessary when starting up the unit at the beginning of the production cycle in winter at low outside temperature, when the temperature in the boiler is still low.

The second additional pipeline connected with the inlet pipe of the heat exchanger creates the possibility of water circulation along the additional circuit together with the main one. That is, part of the water from the main circulation circuit of the tower is diverted to the circulating water tank through an additional circuit. This ensures a decrease in the flow rate of cooling water through the heat exchanger as the flow rate of the vapor from the boiler decreases. Thus, the temperature of the cooling water is maintained at a safe level (12-15 ° C). At the same time, the water temperature at the outlet of the heat exchanger increases accordingly, preventing freezing of water in the cooling tower. The water flow rate is provided by a control valve located on this additional pipeline, which receives signals from the temperature sensor of the circulating water at the outlet of the heat exchanger. This allows, by smoothly adjusting the valve bore, to maintain a safe, predetermined water temperature at the inlet of the tower, which increases the reliability of the installation, eliminating freezing of water in the tower at a low outdoor temperature at the end of the drying cycle, when the vapor flow from the boiler decreases.

The third additional pipeline connected with the boiler through the outlet for the condensation of the heating steam provides this condensate, which does not contain hardness salts, water, evaporated and spent in the circulating water supply system during the operation of the installation. This reduces salt concentration.

hardness in water, preventing clogging of pipes, pump and cooling tower with scale and increasing the reliability of the installation. In addition, it provides a closed production cycle.

Thus, all of the claimed features are significant and solve the problem.

The drawing shows the technological scheme of the installation for the production of feed.

The inventive installation comprises a vacuum boiler 1 and a heat exchanger 2 with a recycled water supply system consisting of a heat exchanger outlet pipe 3, a cooling tower 4, a pipe 5, a circulating water tank 6, a circulation pump 7, and a heat exchanger outlet pipe 8, which form the main circulation circuit in series. The water recycling system also contains a pipe 9 with a control valve 10, for example pressure reducing. The pipeline 9, connected with its outlet to the circulating water tank 6, the circulation pump 7 and the outlet pipe 8 form an additional water circulation circuit. A temperature sensor 11 and a shutter 12 are installed on the outlet pipe 3 of the heat exchanger. The water recycling system also includes a pipe 13 connected to the inlet pipe 3 and the outlet to the circulating water tank 6 and provided with a shutter 14. The pipe 15 is connected to the circulating water tank by the outlet 6, and the inlet - with the boiler 1 through the pipe 16 for the exit of condensate heating steam.

Installation works as follows. Turn on the pump 7 and supply the circulating water to the heat exchanger 2, where it circulates without heating up to supply vapor (juice vapor) from the boiler. At a low outdoor temperature in winter, in order to avoid freezing of water in the cooling tower 4, the circulating water from the heat exchanger 2 is pumped by the pump 7 through the pipe 13 through the circulating water tank 6 and the pipe 8 - back to the heat exchanger 2, bypassing the cooling tower 4. Moreover, the shutter 12 is closed, and the shutter 14 is opened. Then the vapor from boiler 1 enters the heat exchanger 2. At the beginning of the production cycle, its temperature is low and increases gradually, therefore, the temperature of the circulating water also rises. When a safe level (pre-set) of the temperature of the circulating water is reached, it is launched from the heat exchanger 2 along the main circuit - pipe 3 to the cooling tower 4 and back to the heat exchanger 2 through pipe 5, the circulating water tank 6 and pipe 8. In this case, the shutter 12 is opened and the shutter 14 close.

In the production, for example, of meat and bone meal, the most intensive evaporation process from boiler 1 occurs during the first 40 minutes of drying, and then the evaporation rate is reduced. Accordingly, the temperature of the circulating water at the outlet decreases

from the heat exchanger 2 and by the end of the drying process reaches 8 ° C. Therefore, at the end of the process, as at the beginning, there is a danger of freezing of water in the cooling tower 4 in the winter. To prevent this, increase the temperature of the circulating water at the outlet of the heat exchanger 2, by reducing the flow rate of water through it as the flow rate of the vapor decreases. For this, when the temperature of the circulating water deviates from the set value, the control valve 10 is gradually opened according to the signal of the temperature sensor 11. A part of the circulating water then flows from the main circuit into the circulating water tank through pipeline 9, i.e. - to an additional circulation circuit. As a result, the water flow through the heat exchanger 2 will decrease, and the temperature at the outlet of it will begin to increase. As you reach the set temperature value according to the signal from the temperature sensor 11, the outlet of the valve 10 is gradually closed until it is completely closed. Then the circulating water again circulates only along the main circuit. The regulation of the opening of the valve 10 is carried out in manual or automatic mode in accordance with the change in temperature of the circulating water at the outlet of the heat exchanger 2.

The condensate of the heating steam generated during the production process from the boiler 1 enters through the pipe 15 into the circulating water tank 6.

Claims (1)

A feed production plant comprising a boiler connected to a heat exchanger and a reverse water supply system for cooling the latter, consisting of a series of connected piping systems for a cooling tower, a reverse water tank and a circulation pump, characterized in that the reverse water supply system is provided with three additional pipelines connected by their output sections with a tank of circulating water, the inlet sections of two of these pipelines are connected to a heat exchanger, and the inlet section of one of they are connected to the outlet pipe of the heat exchanger, and the inlet section of the other is connected to the inlet pipe of the heat exchanger, an additional pipe that is connected to the inlet pipe of the heat exchanger is equipped with a control valve controlled by a temperature sensor installed on the outlet pipe of the heat exchanger, the inlet section of the third additional pipe is connected to the boiler through its pipe for the exit of condensate of heating steam.