KR100474084B1 - Rendering System - Google Patents

Abstract

The present invention relates to a rendering system for separating and recycling fats and oils of slaughter waste by using heat of high temperature steam.

A rendering system according to the present invention includes a boiler for forming hot steam; A steam chamber to which hot steam generated by the boiler is supplied; A heating treatment chamber into which a treatment object is input and heated by heat of steam inside the steam chamber; A sealed water supply tank disposed below the steam chamber so that condensed water in the lower portion of the steam chamber may be collected by gravity, and supplementary water is supplied from the outside; And a feed pump for supplying water from the closed feed tank to the boiler.

According to the rendering system according to the present invention, since the condensed water in the steam chamber is collected into the sealed water supply tank by the gravity difference and supplied to the boiler, it is possible to prevent heat energy loss due to evaporation of condensed water into the atmosphere, and to install a steam trap This eliminates the need for cost and manpower associated with steam trap maintenance and replacement.

In addition, since the saturated steam of high temperature can be continuously supplied into the steam chamber, the processing time of the target object can be significantly interrupted, thereby improving productivity and economy.

Description

Rendering System

TECHNICAL FIELD The present invention relates to a rendering system, and more particularly, to an improvement of a rendering system that enables the separation and maintenance of slaughter wastes using heat of hot steam.

Since the slaughter waste contains a large amount of fat, that is, oil, it is not only an environmental pollution source but also wastes recyclable resources. Recently, oil, cosmetics, etc. have been separated from the slaughter waste. Increasingly, solids that are used as raw materials for food and from which oil is removed have been recycled into livestock feed.

The rendering system used to effectively separate the fats and oils in the slaughter wastes does not directly heat the slaughter wastes, but rather heats the steam from the boiler to the vessels containing the slaughter wastes. As a result of the heat aging and separation, a rendering system which is generally used currently includes a boiler 1 for forming high temperature steam and steam supplied with high temperature steam generated in the boiler, as shown in FIG. The chambers 2, 2 ', the heat treatment chambers 3, 3' where slaughter waste is introduced and aged by the heat of the steam inside the steam chamber, and the steam traps 4, 4 'allowing only condensate to be discharged from the steam chamber. ), The condensate discharged from the steam trap is collected, the drain tank (5) supplied with supplemental water from the outside, and the condensate collected in the drain tank It consists of a supply pump 6 for supplying to the boiler.

The condensed water fed to the boiler 1 by the feed water pump 6 is heated by a burner and passes through the headers 1a, 2a, 2a 'in a high pressure super heated vapor state, respectively. 2 '), and the heat treatment chambers 3, 3' are double containers inside the steam chamber so that the inlets 3a, 3a 'and the outlets 3b, 3b' protrude out of the steam chambers 2, 2 '. It is formed in the form and is heated uniformly as a whole by the heat of steam supplied from the steam chamber, so that the fat or oil in the slaughter waste introduced into the heat treatment chamber 3 is gradually melted and separated from the solid content without boiling or oxidizing.

The steam supplied to the steam chambers 2 and 2 'is condensed as the temperature decreases as heat is supplied to the heat treatment chamber 3, thereby becoming a wet saturated vapor state. The steam traps 4, 4 'installed in the lower part of the seal are collected.

The steam trap 4 generally uses a bucket or float type. When a predetermined amount or more of condensate enters the steam trap, the bucket or float rises due to the buoyancy of the condensate and causes the valve 4a of the steam trap. 4a ') is opened so that only the condensate is discharged to the drain tank 5.

Condensate discharged from the steam trap (4) to the drain tank (5) is lowered in pressure, part of the evaporation into the atmosphere, the remaining condensate remaining in the water supply tank is mixed with the supplemental water supplied from the outside through the feed water pump (6) Supplied to the boiler.

In general, the replenishment water is supplied by separately installing the replenishment water tank 7 and the replenishment water supply pump 7a, as shown in FIG. .

On the other hand, the water vapor in the slaughter waste generated in the heat treatment chamber during the treatment process is liquefied through the condenser through which the cooling water is circulated, and the waste water is treated. When the slaughter waste is heated and aged for 3 to 4 hours in the heat treatment chamber, the outlets 3b and 3b 'are discharged. ), And then, only the fats and oils are separated through a hopper formed with a filter net and transported to a storage tank, and the remaining solids are processed through a grinder, fats and oil press separators, impurity separators, and the like through feed conveyors. Used.

As described above, the rendering system using the heat of the high temperature steam supplied from the boiler is applied to a drying operation such as an adhesive drying process in the manufacture of corrugated cardboard. In this case, the steam chamber is formed in a tunnel shape and the heat treatment chamber is formed in the inner space. And a conveyor belt through which the corrugated cardboard to be dried is loaded and passed through the heat treatment chamber is configured to dry the adhesive of the corrugated cardboard.

In the conventional rendering apparatus as described above, the steam trap is installed so that the steam inside the steam chamber is not discharged, that is, the latent heat contained in the steam does not escape to the outside of the steam chamber, but the steam trap is discharged from the steam trap to the drain tank. Since much of the condensed water is evaporated and consumed into the atmosphere, there is a problem that the energy efficiency is extremely low.

That is, the steam supplied to the steam chamber in a saturated steam state at high pressure, for example, a pressure of about 8 kgf / cm 2 and a temperature of about 170 ° C. from the boiler is partially phased into a liquid phase as heat is lost to the heat treatment chamber. In this case, only the condensate of the liquid phase is discharged to the drain tank through the steam trap. However, since the drain tank is open to the atmosphere, the condensate discharged to the drain tank has a low pressure. It rapidly evaporates and evaporates to a wet vapor state under atmospheric pressure, that is, a wet vapor state of about 100 ° C. at a saturation temperature at a pressure of about 1 kgf / cm 2, so that a considerable amount of thermal energy of the discharged condensate is re-evaporated in the atmosphere. There is a problem that the loss to the middle, thus the energy efficiency is extremely low, the working environment is extremely poor by the steam discharged.

In addition, a large amount of water is required because the replenishment water must be continuously supplied as much as the amount of steam lost to the atmosphere, and since a large amount of replenishment water at room temperature is mixed and water is supplied to the boiler in a state where the temperature is reduced, There was a problem in that fuel was consumed, and there was a problem in that impurities in the water were continuously formed on the inner wall of the boiler pipe to easily reduce heat transfer efficiency.

In addition, since the flow of steam supplied to the steam chamber is intermittently made by opening and closing the valve of the steam trap, that is, the time limit for the inflow of the hot steam supplied from the boiler to the steam chamber is large, thus requiring a lot of time for the treatment of waste. In addition, the maintenance and replacement of the steam trap takes a lot of cost and time, there was a problem that the productivity and economic efficiency is extremely low.

The present invention is to solve all the problems of the conventional rendering system as described above, rendering the operation cost and the maintenance cost of the device can be drastically reduced by minimizing the replenishment ratio of the water while utilizing heat energy more efficiently. The purpose is to provide a system.

A rendering system according to the present invention for achieving the above object comprises a boiler for forming a high temperature steam; A steam chamber to which hot steam generated by the boiler is supplied; A heating treatment chamber into which a treatment object is input and heated by heat of steam inside the steam chamber; A sealed water supply tank disposed below the steam chamber so that condensed water in the lower portion of the steam chamber may be collected by gravity, and supplementary water is supplied from the outside; And a feed pump for supplying water from the closed feed tank to the boiler.

According to the rendering system according to the present invention, since the condensed water in the steam chamber is collected into the sealed water supply tank by the gravity difference and supplied to the boiler, it is possible to prevent heat energy loss due to evaporation of condensed water into the atmosphere, and to install a steam trap This eliminates the need for cost and manpower associated with steam trap maintenance and replacement.

In addition, since the saturated steam of high temperature can be continuously supplied into the steam chamber, it is possible to significantly interrupt the treatment time of the object.

According to the results of several repeated manufacturing tests according to the present invention, by applying an open impeller feed water pump to the feed pump, even if steam or air in the feed tank does not occur cavitation or water hammering phenomenon occurs It was confirmed that stable operation is possible, and through the installation of a vent pipe connecting the upper part of the sealed water supply tank and the upper part of the steam chamber, the steam pressure of the upper liquid collected in the sealed water supply tank and the upper part of the condensate condensed in the lower part of the steam chamber By maintaining the vapor pressure of the same, it was confirmed that the condensed water collection action by the own weight can be made more smoothly.

Hereinafter, a preferred embodiment of a rendering system according to the present invention will be described with reference to the accompanying drawings.

2 is a view showing an example of a rendering system according to an embodiment of the present invention, the rendering system according to the present invention, the boiler 10 for forming a high temperature water vapor and the high temperature water vapor generated in the boiler The steam chamber 20 to be added, the slaughtered waste being treated, and the heating chamber 30 to be heated by the heat of steam inside the steam chamber, and the condensed water below the steam chamber to be collected by gravity below the steam chamber. It is disposed and is composed of a closed water supply tank 40 for supplying supplemental water from the outside, and a water supply pump 50 for supplying water from the closed water supply tank to the boiler.

The heat treatment chambers 30 and 30 'form a double vessel inside the steam chambers 20 and 20' such that the inlets 30a and 30a 'and the outlets 30b and 30b' protrude out of the steam chambers 20 and 20 '. It is formed so as to be heated uniformly as a whole by the heat of the steam supplied from the steam chamber, a plurality of can be installed for one boiler in accordance with the capacity of the boiler, in this embodiment two heating An example is a system with a processing room.

The upper part of each steam chamber 20, 20 'is connected to the boiler through the headers 10a, 20a, 20a' so that the steam generated in the boiler 10 can be effectively distributed. As the temperature is lowered as heat is supplied to the heat treatment chambers 30 and 30 ', it is condensed to form a wet saturated vapor, and the condensed water thus collected is collected in the lower part of the steam chamber due to the density difference with the steam. In addition, the condensate discharge pipes 31 and 31 ′ in the lower part of the steam chamber are discharged to the sealed water supply tank 40.

As described above, the sealed water supply tank 40 is disposed below the steam chambers 20 and 20 'so that the condensed water in the lower portion of the steam chamber may be collected by gravity, and thus the condensed water discharge pipes 31 of each steam chamber may be disposed. 31 ') may be individually connected to the sealed water supply tank, but as in the present embodiment, it is preferable to connect the condensate collection pipe 41 installed to be inclined about 5 degrees to 15 degrees toward the sealed water supply tank.

Here, the meaning that the sealed water supply tank 40 is disposed below the steam chambers 30 and 30 'does not mean that the upper end of the sealed water supply tank itself is necessarily lower than the lower end of the steam chamber, and in a normal operation state, Compared to the condensate level in the steam chamber, the condensate level collected in the sealed water tank is low, which means that the condensate in the steam chamber can be collected into the sealed water tank.

The upper part of the sealed water supply tank and the upper part of the steam chamber are interconnected by the vent pipe 42, thereby maintaining the same steam pressure in the upper part of the closed water supply tank and the steam pressure in the upper part of the steam chamber, that is, acting on the upper part of the condensate water on both sides. By maintaining the same pressure at all times, it is possible to more smoothly perform the action of collecting the condensed water according to the water level difference, that is by its own weight.

The replenishment water supplemented to the sealed water supply tank 40 may be supplied by installing an automatic adjustment on / off valve in the direct water line. However, as in the present embodiment, the replenishment water tank 60 and the replenishment water supply pump 60a may be supplied. It is preferable to install and supply separately. Since the inside of the sealed water supply tank is connected to the steam chamber and maintained at a high pressure, a check valve 60b is provided in the supplementary water pipe so as to prevent the high pressure steam inside the sealed water supply tank from flowing back to the supplement water tank side. The replenishment water supply pump is turned on / off according to the detection result of the water level sensor installed inside the hermetic water supply pump so as to maintain a constant level in the hermetic water supply tank.

On the other hand, the water feed pump used in the conventional rendering system was a closed impeller feed water pump to which a closed impeller in which both sides of the vanes 51 are closed by a disc 52 is applied as shown in FIG. 3A. As a result of applying the test to the present invention, it was confirmed that the operation of the device was not performed smoothly due to the cavitation or water hammering phenomenon caused by the flow of steam or air bubbles into the pump. As a result of testing by applying an open impeller, that is, an open impeller feed pump with an impeller open on both sides of the vanes 51, even when steam or air in the feed tank flows into the pump, the friction loss in the vicinity of the impeller is small. Incoming gases can flow concentrated in condensate, so cavitation and water hammering It was confirmed that stable operation was possible without.

Reference numeral 53 denotes a reinforcing ring for reinforcing the strength of the vane 53.

The feed water pump is turned on / off according to the detection result of the water level sensor installed inside the boiler so that the water level in the boiler can be kept constant.

According to the rendering system according to the present invention as described above, since the condensed water in the steam chamber is collected into the sealed water supply tank by the gravity difference and supplied to the boiler, it is possible to prevent the loss of thermal energy due to the evaporation of condensate to the atmosphere, fuel costs It can save a lot of cost, and there is no need to install steam traps, which can reduce the cost or manpower of maintenance and replacement of steam traps.

In addition, by supplying water of high temperature and high pressure to the boiler, the load fluctuation of the boiler is small and high temperature saturated steam can be continuously supplied to the inside of the steam chamber, which can drastically control the processing time of the object and evaporate Since only the minimum supplementary water required for operation is supplied without water discharged into the atmosphere, it is possible to minimize scale formation inside the boiler by the water, thereby maintaining the boiler in a high efficiency state and minimizing the water cost.

1 is a block diagram illustrating an example of a conventional rendering system.

2 is a block diagram of a rendering system according to an embodiment of the present invention.

Figures 3a and 3b is a perspective view showing an example of a closed type impeller applied to a conventional rendering system and an open type impeller applied to the feed pump of the present invention.

<Explanation of symbols for the main parts of the drawings>

10: boiler 20: steam chamber

30: heat treatment chamber 40: sealed water supply tank

50: feed pump

Claims (3)

A boiler for forming hot steam; A steam chamber to which hot steam generated by the boiler is supplied; A heating treatment chamber into which a treatment object is input and heated by heat of steam inside the steam chamber; A sealed water supply tank disposed below the steam chamber so that condensed water in the lower portion of the steam chamber may be collected by gravity, and supplementary water is supplied from the outside; And a feed water pump for supplying water from the sealed water supply tank to the boiler. The rendering system according to claim 1, further comprising a vent pipe connecting an upper portion of the sealed water supply tank and an upper portion of the steam chamber to each other. 3. The rendering system of claim 1 or 2, wherein the feed pump is an open impeller feed pump.