KR102461907B1 - Heating apparatus of screw conveyor for transfering food leachate - Google Patents

Abstract

The present invention relates to a heating apparatus of a screw conveyor for transferring food waste, which can improve the drying efficiency of food waste and increase the amount of oil extracted from food waste by heating screw conveyor equipment serving to transfer the food waste crushed in a previous process to a subsequent process. The heating apparatus of a screw conveyor for transferring food waste improves a jacket structure of the screw conveyor equipment, which transfers food waste to the next process after crushing in the pretreatment process, into a high-strength pipe-type structure with a large heat transfer area, develops and applies a high-temperature heat source supply device to increase the amount of oil extracted from crushed food waste regardless of the season in a dehydration process following the crushing process, thereby reducing costs and improving sludge drying efficiency and feed product quality so as to enhance corporate competitiveness. The heating apparatus comprises a screw conveyor (16), a heating apparatus (19), a recovery-side circulation line (21), a circulation pump (22), and a coil-type pipe (23).

Description

Heating device of screw conveyor for food waste transfer

The present invention relates to a heating device for a screw conveyor for transporting food waste, and more particularly, by heating a screw conveyor facility serving to transport the food waste crushed in the previous process to the subsequent process to improve the drying efficiency of food waste and sound It relates to a heating device for a screw conveyor for transporting food waste that can increase the amount of oil extracted in waste.

In general, the treatment method applied in the field is to selectively select various foreign substances that are originally mixed in food waste in any process, convert the solid to as small as possible and recover it as much as possible. A lot of attention is focused on the process configuration of the pre-treatment to facilitate each subsequent treatment after effectively separating the material from the cost-effective aspect in an arbitrary ratio.

Accordingly, various unit facilities have been developed that can satisfy the goals pursued by resource-recycling technology to some extent in the pre-treatment process of separating the solids and the talismant at an arbitrary ratio, which is being applied to the field. From the first stage, it is important to satisfy the functions of sorting, pulverizing and separating various solid substances contained in food waste according to the purpose.

Usually, in the food waste pretreatment process, the food waste is brought in, a storage hopper, a crusher, and a dehydrator, and then the dehydrated sludge discharged from the dehydrator is put into the dryer via an intermediate storage hopper, while the food waste water discharged from the dehydrator is a low-speed separator, three-phase After going through the separator, the sludge discharged from the three-phase separator is sent to the intermediate storage hopper, the food wastewater is consigned to the outside, and the oil discharged from the three-phase separator goes through an oil purification device for shipment and sale.

At this time, the food waste transport between each facility is handled by the screw conveyor.

Currently, in the process of transporting to the next process after pre-treatment of crushed food waste, due to the high moisture content of the crushed food waste, it is affected by the temperature drop in the rest of the season except for summer, and as a result, oil (animal, vegetable) It is a factor of a decrease in by-product sales due to poor extraction conditions.

In addition, the mixing of oily substances in the dehydrated sludge fed into the dryer increases due to the poor oil extraction state, and the generation of oily vapors (wet, oily vapor) in the feed discharged after drying intensifies, and this intensifies the equipment in the feed grinding and sorting process There is a problem that frequent clogging occurs due to internal adhesion, etc., and the high content of oily substances in the final feed product is a factor in product quality deterioration such as poor feed production.

Public Utility Model Publication No. 20-1998-0006836 Laid-Open Patent Publication No. 10-2009-0033575

Therefore, the present invention has been devised in view of such a point, and the jacket structure of the screw conveyor facility, which transports food waste to the next process after crushing in the pre-treatment process, is improved to a high-strength pipe-type structure with a large heat transfer area, and high temperature In the dehydration process that follows the crushing process by developing and applying the heat source supply device of An object of the present invention is to provide a heating device of a screw conveyor for transporting food waste that can strengthen the

In order to achieve the above object, the heating device of the screw conveyor for transporting food waste provided by the present invention has the following characteristics.

The heating device of the screw conveyor for transporting food waste is a screw conveyor as a means for transporting food waste while being driven by the power of a motor, the screw conveyor comprising a screw and a body, and a jacket installed on the outer periphery of the body while having an inlet and an outlet, and the A heating device comprising a tank having an inlet and an outlet as means for supplying a heat source to the screw conveyor and an electric heater installed inside the tank for heating the heat source, and a tank for circulation of the heat source between the screw conveyor side and the heating device side A supply-side circulation line connected between the outlet of the and the inlet of the jacket, a recovery-side circulation line connected between the inlet of the tank at the outlet of the jacket, and a circulation pump installed on the supply-side circulation line.

Therefore, the heating device of the screw conveyor for food waste transfer is characterized in that it can heat the food waste transferred along the screw conveyor while circulating a heat source between the heating device side and the screw conveyor side.

Here, the jacket of the screw conveyor may be formed of a circular pipe jacket, a “U”-shaped jacket, etc. that completely surrounds the outer periphery of the main body in a concentric circle shape.

At this time, thermal medium oil, circulating water, etc. may be used as a heat source circulating between the heating device side and the screw conveyor side.

In particular, when using circulating water as a heat source circulating between the heating device side and the screw conveyor side, the heating device of the screw conveyor for food waste transfer is installed inside the tank and a coil-type pipe connected to the inlet and the outlet is further added. Accordingly, there is a feature that can heat the circulating water supplied to the screw conveyor through heat exchange between the thermal medium oil filled in the tank and the circulating water flowing through the inside of the coil-type pipe.

As a preferred embodiment, the electric heater of the heating device may be installed in a structure located inside the coil-type pipe with two sets of left and right taking a downwardly inclined posture inward from both side portions of the tank.

In addition, the coil-type pipe may be formed of a large-capacity coil-type pipe and a small-capacity coil-type pipe connected to each inlet and outlet while being installed inside the tank, and accordingly, a large-capacity coil-type pipe according to the flow rate required by the screw conveyor. There is a feature that a pipe or a small-capacity coil-type pipe can be selectively used.

As a preferred embodiment, the tank of the heating device is provided with a thermal oil inlet for inputting the thermal oil and a thermal oil outlet for discharging the thermal oil, and a level check tube may be installed between the thermal oil inlet and the thermal oil outlet. , it is possible to check the amount of heating medium filled in the tank.

The heating device of the screw conveyor for food waste transport provided by the present invention has the following effects.

1) By improving the screw conveyor equipment that transports the food waste to the next process after crushing it from the existing “U”-shaped jacket type to the round pipe jacket type, the heat transfer area is relatively large compared to the jacket of the existing screw conveyor equipment, and the structural strength of the jacket is improved. It has a high lifespan, and it is possible to supply a high-temperature heat source (eg, hot water, thermal oil, etc.) to the jacket side, thereby increasing the efficiency of heating food waste (sludge, etc.).

2) Heating the heat sources such as thermal oil, steam, and hot water supplied to the jacket of the screw conveyor facility with electricity at night, supplying and circulating the jacket of each screw conveyor facility at a high temperature (eg, 80 to 90 ° C) By adopting it, there is an economic effect in terms of energy utilization by using electricity at night.

3) It is possible to increase the extraction amount of oil in the food waste by increasing the heating efficiency in the process of transferring the food waste of the screw conveyor facility, thereby reducing the cost as well as enhancing the competitiveness of the companies in the same industry by improving the efficiency of food waste treatment and the quality of dry feed. There is an effect that can promote increase.

4) It has the effect of maintaining the extraction amount that has increased the oil content in the crushed food waste regardless of the seasonal factors.

5) By removing organic substances, dehydration of food waste can be smoothly dried and the drying efficiency can be increased.

6) There is an effect that can improve productivity by increasing processing efficiency, such as reducing clogging inside equipment during dry material pulverization and sorting processes.

7) It has the effect of improving the quality of the product, such as the color of the feed, by reducing organic substances in the feed.

8) It is easy to maintain facilities by reducing the generation of oil vapors in the process of drying food waste, and it has the effect of improving the working environment by reducing the generation of odorous substances.

9) By adopting a heating device that heats hot water through the heat exchange action between thermal oil and hot water, high-temperature hot water (circulating water) can be circulated quickly and smoothly and provided to the screw conveyor equipment in terms of thermal efficiency maintenance. has a beneficial effect.

10) By adopting a heating device with two types of hot water pipes with different capacities as well as applying a hot water pipe with a coil-type pipe structure, it is possible to increase thermal efficiency by securing sufficient heat transfer area and to actively cope with various capacities of screw conveyor facilities. can have an effect.

1 and 2 are perspective views showing a heating device of a screw conveyor for transferring heat medium oil circulation type food waste according to an embodiment of the present invention;
3 and 4 are perspective views showing a heating device of a screw conveyor for transferring heat medium oil circulation type food waste according to another embodiment of the present invention;
5 is a cross-sectional view showing a screw conveyor to which a pipe type jacket is applied in the heating device of the screw conveyor for transporting food waste according to an embodiment of the present invention;
6 is a cross-sectional view showing a screw conveyor to which a "U" type jacket is applied in the heating device of the screw conveyor for transporting food waste according to an embodiment of the present invention;

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2 are perspective views illustrating a heating device of a screw conveyor for transferring heat medium oil circulation type food waste according to an embodiment of the present invention.

1 and 2, an example of using thermal oil as a heat source circulating between the heating device 19 side and the screw conveyor 16 side is shown here, and accordingly, the heating device 19 side It is possible to heat the food waste transported along the screw conveyor 16 while circulating the thermal oil between the screw conveyor 16 and the screw conveyor 16 .

To this end, the heating device of the screw conveyor for transferring the food waste includes a screw conveyor 16 as a means for transferring the crushed food waste.

The screw conveyor 16 is a means for transporting food waste while rotating the screw 11 with the power of the motor 10. One side of the food waste inlet 27 for inputting the food waste and the opposite side for discharging the food waste. The main body 12, in which the food waste outlet 28 is formed, respectively, is installed in a coaxial structure inside the main body 12, and is supported at both ends by bearings and is connected to the shaft of the motor 10 through the transmission means It includes a screw (11).

And, a heat source, that is, a jacket 15 through which thermal oil circulates is installed on the outer periphery of the main body 12, and is transferred from the inside of the main body 12 by the high-temperature thermal oil flowing inside the installed jacket 15 The food waste can be heated.

The jacket 15 of the main body 12 has an inlet 13a on one side and an outlet 14a on the opposite side, through which the thermal oil enters and exits, respectively, and the thermal oil that enters the jacket through the inlet 13a at this time is the jacket. After performing a heat exchange action with the food waste while flowing along the longitudinal direction, it is possible to escape to the outside of the jacket through the outlet 14a.

In particular, the jacket 15 installed on the outer periphery of the screw conveyor 16 is formed in the form of a circular pipe that completely surrounds the outer periphery of the main body 12 concentrically (see FIG. 5 ).

In this way, the jacket 15 in the form of a circular pipe forms a structure that completely surrounds the body 12 over the entire length of the body, and also removes food waste in the body at a uniform distance (eg, distance from the center of the body) over the entire circumference of the body. By heating, a relatively large heat transfer area can be secured compared to the conventional "U"-shaped jacket, and uniform heating is possible, and thus, there is an advantage in that it is possible to increase the heating efficiency of food waste.

In addition, in the case of the jacket 15, it is made in the form of a circular pipe, so the structural strength is high, and accordingly, there is an advantage in that the life of the screw conveyor including the jacket 15 can be extended.

As another example, the jacket 15 installed on the outer periphery of the screw conveyor 16 may be installed as a "U"-shaped jacket installed on the outer periphery of the main body 12 (see FIG. 6 ).

In addition, the heating device of the screw conveyor for transporting food waste includes a heating device 19 as a means for supplying the heating medium oil heated to a high temperature (eg, about 80 to 90° C.) to the screw conveyor 16 side.

The heating device 19 consists of a tank 17 having an inlet 13b on one side through which the thermal oil enters and an outlet 14b on the opposite side through which the thermal oil exits, and a plurality of electric heaters 18 for heating the thermal oil in the tank. do.

Here, the tank 17 is a circular tank installed in a structure supported by the frame structure 29, and serves to store a certain amount of thermal oil and heat the thermal oil at this time.

A thermal oil inlet 24 for inputting the thermal oil is installed on the upper side of the tank 17, and a thermal oil outlet 25 for discharging the thermal oil is installed on the lower side of the tank 17.

At this time, the thermal oil inlet 24 and the thermal oil outlet 25 can be used in operation situations such as when injecting thermal oil before operation of the facility, when replenishing thermal oil, when exchanging thermal oil, etc. .

As a preferred embodiment, between the thermal oil inlet 24 and the thermal oil outlet 25, a level check tube 26 in the form of a transparent tube having a scale (not shown), etc. is vertically installed, and accordingly, the tank 17 ), the operator can visually check the amount of thermal oil filled inside, so that in case of shortage, follow-up measures such as replenishment of thermal oil can be easily taken.

And, the electric heater 18 of the heating device 19 is composed of two sets of left and right that take an obliquely downwardly inclined posture toward the inside from both side portions of the tank 17 .

For example, six electric heaters 18 may be provided at opposite positions facing each other on both sides of the tank 17 .

In addition, at least one temperature sensor mounting hole 30 , preferably two temperature sensor mounting holes 30 are installed at the upper end of the tank 17 , and the temperature sensor mounting hole 30 installed in this way has a temperature A sensor (not shown) may be installed.

Accordingly, the temperature sensor detects the temperature of the thermal oil filled in the tank 17, and the temperature value sensed by the temperature sensor at this time, that is, the temperature value of the thermal oil is sent to the controller (not shown), the controller In , it is possible to automatically adjust the temperature of the thermal oil by a method of appropriately controlling the number of operation of the electric heater 18 .

That is, the heating device 19 can appropriately adjust the temperature of the thermal oil circulating on the screw conveyor 16 side while actively responding to seasonal temperature changes, various processing capacities of the screw conveyor 16, and the like, thus reducing energy use. It is possible to improve the efficiency, of course, it is possible to increase the heating efficiency of food waste and processing efficiency.

In particular, the heating device 19 can be operated using late-night electricity that has accumulated surplus power in late-night time zones when electricity consumption is relatively low, and accordingly, industrial or household businesses and households can expand their use of late-night electricity. Not only can it contribute to the supply and demand of electricity, such as, but also greatly reduce electricity consumption, which has the advantage of economical facility operation.

In addition, the heating device of the screw conveyor for transporting food waste is a means for providing a passage through which thermal oil can circulate between the screw conveyor 16 side and the heating device 19 side, and the supply side circulation line 20 and the recovery side circulation It includes a line 21, and a circulation pump 22 for pumping the thermal oil.

The supply-side circulation line 20 is a pipeline and is connected between the outlet 14b of the tank 17 and the inlet 13a of the jacket 15 .

The return-side circulation line 21 is also a pipeline, and is connected between the inlet 13b of the tank 17 of the outlet 14a of the jacket 15 .

In addition, the circulation pump 22 is connected and installed on the supply side circulation line 20 .

Accordingly, when the circulation pump 22 is operated, the heating medium oil heated inside the tank of the heating device 19 is circulated inside the tank 17 → the supply side circulation line 20 → the inside of the jacket 15 → the recovery side circulation. Line 21 → It is possible to heat the food waste transferred from the inside of the screw conveyor 16 while circulating along the repetitive circulation path leading to the inside of the tank 17, and eventually heating efficiency in the process of transferring the food waste It is possible to increase the oil extraction amount and increase the food waste treatment efficiency.

3 and 4 are perspective views illustrating a heating device of a screw conveyor for transferring heat medium oil circulation type food waste according to another embodiment of the present invention.

3 and 4, an example of using circulating water (hot water) as a heat source circulating between the heating device 19 side and the screw conveyor 16 side is shown here, and accordingly, the heating device ( 19) It is possible to heat the food waste transported along the screw conveyor 16 while circulating the circulating water between the side and the screw conveyor 16 side.

To this end, the heating device of the screw conveyor for transferring the food waste includes a screw conveyor 16 as a means for transferring the crushed food waste.

The screw conveyor 16 is a means for transporting food waste while rotating the screw 11 with the power of the motor 10, and has a food waste inlet 27 on one side for inputting food waste and the opposite side for discharging food waste. The main body 12, in which the food waste outlet 28 is formed, respectively, is installed in a coaxial structure inside the main body 12, and is supported at both ends by bearings and is connected to the shaft of the motor 10 through the transmission means It includes a screw (11).

In addition, a heat source, that is, a jacket 15 through which circulating water circulates, is installed on the outer periphery of the main body 12 , and is transferred from the inside of the main body 12 by the high-temperature circulating water flowing inside the installed jacket 15 . The resulting food waste can be heated.

An inlet 13a on one side and an outlet 14a on the opposite side are respectively formed in the jacket 15 of the main body 12, and the circulating water that enters the jacket through the inlet 13a at this time is the jacket. After performing a heat exchange action with the food waste while flowing along the longitudinal direction, it is possible to escape to the outside of the jacket through the outlet 14a.

In particular, the jacket 15 installed on the outer periphery of the screw conveyor 16 is formed in the form of a circular pipe that completely surrounds the outer periphery of the main body 12 concentrically (see FIG. 5 ).

In this way, the jacket 15 in the form of a circular pipe forms a structure that completely surrounds the body 12 over the entire length of the body, and also removes food waste in the body at a uniform distance (eg, distance from the center of the body) over the entire circumference of the body. By heating, a relatively large heat transfer area can be secured compared to the conventional "U"-shaped jacket, and uniform heating is possible, and thus, there is an advantage in that it is possible to increase the heating efficiency of food waste.

In addition, in the case of the jacket 15, it is made in the form of a circular pipe, so the structural strength is high, and accordingly, there is an advantage in that the life of the screw conveyor including the jacket 15 can be extended.

As another example, the jacket 15 installed on the outer periphery of the screw conveyor 16 may be installed as a "U"-shaped jacket installed on the outer periphery of the main body 12 (see FIG. 6 ).

As a preferred embodiment, a make-up water tank 31 is connected to the jacket 15 of the screw conveyor 16, and the make-up water tank 31 installed in this way is connected to the heating device 19 side and the screw conveyor 16. It plays a role of replenishing the circulating water circulating between the sides with an appropriate flow rate.

In addition, the heating device of the screw conveyor for transporting food waste includes a heating device 19 as a means for supplying circulating water heated to a temperature of about 80 to 90° C. to the screw conveyor 16 side.

The heating device 19 includes an inlet 13b on one side where circulating water enters and an outlet 14b on the other side where circulating water exits, as well as a thermal oil inlet 24 and thermal oil on one side for inputting and discharging thermal oil filled in the tank. It consists of a tank 17 having a discharge port 25, and a plurality of electric heaters 18 that heat the heat medium oil in the tank and consequently heat the circulating water.

Here, the tank 17 is a circular tank installed in a structure supported by the frame structure 29, and serves to store a certain amount of thermal oil and heat the circulating water through the thermal medium at this time. do.

A thermal oil inlet 24 for inputting the thermal oil is installed on the upper side of the tank 17, and a thermal oil outlet 25 for discharging the thermal oil is installed on the lower side of the tank 17.

At this time, the thermal oil inlet 24 and the thermal oil outlet 25 can be used in operation situations such as when injecting thermal oil before operation of the facility, when replenishing thermal oil, when exchanging thermal oil, etc. .

As a preferred embodiment, a level check pipe 26 having a valve is installed between the thermal oil inlet 24 and the thermal oil outlet 25, and accordingly, the amount of the thermal medium filled in the tank 17 is adjusted. It is possible for the operator to visually check through the level check tube 26 .

And, the electric heater 18 of the heating device 19 is composed of two sets of left and right that take an obliquely downwardly inclined posture toward the inside from both side portions of the tank 17 .

For example, six electric heaters 18 may be provided at opposite positions facing each other on both sides of the tank 17 .

In addition, at least one temperature sensor mounting hole 30 , preferably two temperature sensor mounting holes 30 are installed at the upper end of the tank 17 , and the temperature sensor mounting hole 30 installed in this way has a temperature A sensor (not shown) may be installed.

Accordingly, the temperature sensor detects the temperature of the thermal oil filled in the tank 17, and the temperature value sensed by the temperature sensor at this time, that is, the temperature value of the thermal oil is sent to the controller (not shown), the controller In , it is possible to automatically adjust the temperature of the circulating water provided to the screw conveyor 16 by automatically adjusting the temperature of the thermal oil by appropriately controlling the number of operation of the electric heater 18 .

That is, the heating device 19 can appropriately adjust the temperature of the circulating water circulating on the screw conveyor 16 side while actively responding to seasonal temperature changes, various processing capacities of the screw conveyor 16, and the like, and thus use energy. Of course, it is possible to improve the efficiency of the food waste heating efficiency, it is possible to increase the processing efficiency.

In particular, the heating device 19 can be operated using late-night electricity that has accumulated surplus power in late-night time zones when electricity consumption is relatively low, and accordingly, industrial or household businesses and households can expand their use of late-night electricity. Not only can it contribute to the supply and demand of electricity, such as, but also greatly reduce electricity consumption, which has the advantage of economical facility operation.

In particular, the heating device of the screw conveyor for transporting food waste heats the thermal oil with an electric heater 18, and then heats the circulating water with the heated thermal oil and provides it to the screw conveyor 16 side. do.

To this end, circulating water circulates as a heat source between the heating device 19 side and the screw conveyor 16 side, and one side is connected to the inlet 13b where the circulating water enters the tank 17, and at the same time, the circulating water A coiled pipe 23 connected to the outlet 14b and the other end is installed.

Accordingly, the circulating water entering through the inlet 13b passes through the coiled pipe 23 in the inside of the tank 17 and then exits through the outlet 14b, and during this process, the coiled pipe 23 ) and the heat medium oil filled in the tank 17, that is, the heat medium oil heated by the electric heater 18, so that heat exchange is made between the circulating water flowing inside the The circulating water can be heated to a predetermined temperature.

In addition, the coiled pipe 23 is installed inside the tank 17 and is connected to each inlet 13b and outlet 14b compared to a large capacity coiled pipe 23a, that is, a small capacity coiled pipe 23b. A large-capacity coiled pipe 23a having a relatively large diameter and pipe surface area, and a small-capacity coiled pipe 23b installed inside the tank 17 and connected to each inlet 13b and outlet 14b, that is, a large capacity It is composed of a small capacity coiled pipe 23b having a relatively small diameter and pipe surface area compared to the coiled pipe 23a.

The large-capacity coil-type pipe 23a and the small-capacity coil-type pipe 23b can be installed while forming a coaxial structure with each other inside the tank 17, and the small-capacity coil-type pipe ( 23b) can be installed in a structure in which they are coaxially arranged side by side.

The large-capacity coiled pipe 23a and the small-capacity coiled pipe 23b installed in this way are a pair of inlets 13b and outlets 14b installed in the tank 17, that is, two inlets 13b and two Each can be individually connected to the outlet 14b.

Accordingly, it is possible to circulate the circulating water by selectively using the large-capacity coil-type pipe 23a and the small-capacity coil-type pipe 23b according to the flow rate required by the screw conveyor 16 side.

As an example, a large-capacity coil-type pipe 23a is connected from two inlets 13b in the tank 17 to the recovery-side circulation line 21 extending from the outlet 14a side of the screw conveyor 16 . A large-capacity coil-type pipe 23a is connected to the inlet 13b located in It can be used by connecting to the connected outlet (14b).

As another example, a small-capacity coil-type pipe 23b is connected among the two inlets 13b in the tank 17 to the recovery-side circulation line 21 extending from the outlet 14a side of the screw conveyor 16 . A small-capacity coil-type pipe 23b is connected to the inlet 13b located in It can be used by connecting to the connected outlet (14b).

As a preferred embodiment, after branching the return-side circulation line 21 extending from the outlet 14a side of the screw conveyor 16 into two lines, each branch line is divided into two inlets 13b in the tank 17 . ) and at the same time as installing a solenoid (not shown) capable of switching between opening and closing under the control of the controller at the branch point of the branch line at this time, the supply side circulation line 20 extending toward the inlet 13a of the screw conveyor 16 ) also branched into two lines, then each branch line is connected to the two outlets 14b of the tank 17, and at the same time, at the branch point of the branch line at this time, a solenoid (not shown) that can be switched on and off by the control of the controller. ) can be installed and used.

Accordingly, it is possible to heat while circulating the circulating water to the large-capacity coil-type pipe 23a side or the small-capacity coil type pipe 23b side, respectively, according to the switching of the opening and closing directions of the recovery side and the supply side solenoid by the output control of the controller.

In addition, the heating device of the screw conveyor for transporting food waste is a means for providing a passage through which circulating water can circulate between the screw conveyor 16 side and the heating device 19 side, and the supply side circulation line 20 and the recovery side circulation a line 21 and a circulation pump 22 for pumping circulating water.

The supply-side circulation line 20 is a pipeline and is connected between the outlet 14b of the tank 17 and the inlet 13a of the jacket 15 .

The return-side circulation line 21 is also a pipeline, and is connected between the inlet 13b of the tank 17 of the outlet 14a of the jacket 15 .

In addition, the circulation pump 22 is connected and installed on the supply side circulation line 20 .

Therefore, when the circulation pump 22 is operated, the circulating water heated inside the tank of the heating device 19 is circulated inside the tank 17 → the supply side circulation line 20 → the inside of the jacket 15 → the recovery side circulation. Line 21 → It is possible to heat the food waste transferred from the inside of the screw conveyor 16 while circulating along the repeated circulation path leading to the inside of the tank 17, and eventually heating efficiency in the process of transferring the food waste It is possible to increase the oil extraction amount and increase the food waste treatment efficiency.

As such, in the present invention, the jacket structure of the screw conveyor facility for transferring food waste between processes is improved to a high-strength pipe-type structure with a large heat transfer area, and a high-temperature heat source supply device is developed and applied. By providing a device for heating the food waste transported along the screw conveyor, it is possible to increase the extraction amount of oil in the crushed food waste regardless of the season in the dehydration process following the crushing process, thereby reducing cost as well as sludge drying efficiency And by improving the quality of feed products, corporate competitiveness can be strengthened.

10: motor
11: screw
12: body
13a, 13b: entrance
14a, 14b: exit
15 : jacket
16: screw conveyor
17 : Tank
18: electric heater
19: heating device
20: supply side circulation line
21: return side circulation line
22: circulation pump
23: coiled pipe
23a: large-capacity coiled pipe
23b: small capacity coiled pipe
24: thermal oil inlet
25: thermal oil outlet
26: pipe for level check
27: food waste inlet
28: food waste outlet
29: frame structure
30: temperature sensor mounting hole
31: make-up water tank

Claims (7)

A jacket installed on the outer periphery of the main body 12 while driving with the power of the motor 10 and having a screw 11 and a main body 12, and an inlet 13a and an outlet 14a as a means for transporting food waste. a screw conveyor (16) comprising (15);
As a means for supplying a heat source to the screw conveyor 16, a tank 17 having an inlet 13b and an outlet 14b and an electric heater 18 installed in the tank 17 for heating the heat source are provided. a heating device (19) comprising;
The supply side circulation line 20 and the jacket connected between the outlet 14b of the tank 17 and the inlet 13a of the jacket 15 for circulation of a heat source between the screw conveyor 16 side and the heating device 19 side a return-side circulation line 21 connected between the outlet 14a of (15) and the inlet 13b of the tank 17;
a circulation pump 22 installed on the supply side circulation line 20;
containing, while circulating a heat source between the heating device 19 side and the screw conveyor 16 side, it is possible to heat the food waste transferred along the screw conveyor 16, and the heating device 19 side and the screw In the case of using circulating water as a heat source circulating between the conveyor 16 side, it further includes a coiled pipe 23 connected to the inlet 13b and the outlet 14b while being installed inside the tank 17, , Food waste characterized in that it is possible to heat the circulating water supplied to the screw conveyor 16 side through heat exchange between the heat medium oil filled in the tank 17 and the circulating water flowing through the inside of the coiled pipe 23 Heating device of screw conveyor for transport.
The method according to claim 1,
The jacket 16 of the screw conveyor 16 is a heating device for a screw conveyor for transporting food waste, characterized in that it is made of a circular pipe shape that completely surrounds the outer periphery of the main body 12 concentrically.
The method according to claim 1,
A heating device for a screw conveyor for transporting food waste, characterized in that heat medium oil or circulating water is used as a heat source circulating between the heating device 19 side and the screw conveyor 16 side.
delete The method according to claim 1,
The electric heater 18 of the heating device 19 is composed of two sets of left and right that take a downwardly inclined posture inward from both side portions of the tank 17 and is positioned inside the coiled pipe 23. A heating device of a screw conveyor for transporting food waste, characterized in that it is installed.
The method according to claim 1,
The coiled pipe 23 is installed inside the tank 17 and is composed of a large-capacity coiled pipe 23a and a small-capacity coiled pipe 23b connected to each inlet 13b and outlet 14b, and a screw conveyor (16) A heating device for a screw conveyor for transporting food waste, characterized in that it is possible to selectively use a large-capacity coil-type pipe (23a) or a small-capacity coil-type pipe (23b) according to the flow rate required by the side.
The method according to claim 1,
In the tank 17 of the heating device 19, a thermal oil inlet 24 for inputting the thermal oil and a thermal oil outlet 25 for discharging the thermal oil are installed, and a thermal oil inlet 24 and a thermal oil outlet ( 25) between the pipe 26 for checking the level,
A heating device for a screw conveyor for transporting food waste, characterized in that it is possible to check the amount of heating medium filled in the tank (17).

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