KR20170099938A - Waste treatment installation - Google Patents

Abstract

At least one waste incinerator unit (4) having at least one waste storage unit (2), at least one waste supply unit (3), an outlet (7) and at least one flue gas The present invention relates to a waste disposal facility 1 of a marine vessel V that includes a flue gas pipeline 8. In order to cool the flue gas to a desired degree, the flue gas pipeline 8 is provided with an inline cooling device 10 for cooling the discharged flue gas to a predetermined temperature. The cooling device 10 includes a water injection mechanism 11 having a water discharge nozzle 12 for direct supply of a water stream to the flue gas pipeline 8. In addition, the cooling device 10 includes a pressurized air injection mechanism 16 for supplying pressurized air into the water stream.

Description

{WASTE TREATMENT INSTALLATION}

The present invention relates to a marine vessel refuse disposal facility comprising at least one refuse receiving unit, at least one refuse feed unit, at least one incinerator unit provided with an outlet, and at least one flue gas pipeline According to the preamble of claim 1. The present invention also relates to a method for cooling flue gas in a marine vessel waste treatment facility according to the preamble of claim 9.

Various garbage disposal facilities are known in the prior art. A general waste disposal facility for treating food waste and so-called litter, such as household garbage, includes a waste supply hopper from which waste is supplied to the transfer screw, which transports the waste to the incinerator. Incineration of garbage is carried out in an incinerator, for example at a temperature of 850 ° C to 1200 ° C. An example of such a facility is disclosed in European Patent Publication EP 1 384 948 B1.

In such known refuse disposal facilities, the flue gas generated by the combustion of waste has a very high temperature to produce dioxin chemicals.

Several solutions have been proposed to reduce the amount of dioxin chemicals. CN 102230627 describes a ground-based waste burner with a separate gas quenching tower. The cooling tower is provided with a coolant sprayer to lower the flue gas temperature. CN 103644570 discloses another ground installation configuration in which a high pressure water mist is used to quench the flue gas associated with the furnace. These are technically complex and space-consuming configurations. EP 1 065 444 B1 discloses another exhaust gas cooling device in which high pressure water and high pressure air are introduced into separate cooling chambers through separate mixing mechanisms or high pressure hot water is introduced into the exhaust gas duct. These are technically complex structures that are prone to very expensive and functional failures. In addition, conventional arrangements require space, which is unsuitable for offshore vessels.

European Patent Publication EP 1 384 948 B1 Chinese Published Patent Publication CN 102230627 Chinese Published Patent Publication CN 103644570 European Patent Publication EP 1 065 444 B1

It is an object of the present invention to achieve an efficient marine vessel waste disposal facility with a simple flue gas cooling system that avoids the drawbacks of the prior art and meets the requirements of the relevant International Maritime Organization (IMO) regulations. This object is achieved by a marine marine garbage disposal facility according to claim 1 and a flue gas cooling method of a marine marine garbage disposal facility according to claim 9.

The basic technical idea of the present invention is to effectively cool the flue gas within a short distance after the flue gas enters the flue gas pipeline from the outlet of the incinerator unit. This is accomplished by an inline cooling device installed in the flue gas pipeline. The cooling device includes a water injection mechanism having a water discharge nozzle for direct supply of a water stream from the predetermined location of the flue gas pipeline to the flue gas pipeline. The cooling device further includes a pressurized air injection mechanism for supplying pressurized air to the water stream.

An advantage of the present invention is that no auxiliary cooling reactor is required. It is also sufficient to install a technically simple cooling device and a temperature measuring device in the flue gas pipeline. This means that as a technically advantageous and inexpensive means, there is no need for additional space for mounting on marine vessels.

The pressurized air supplied to the water stream disperses water into mist and has a maximum surface for cooling the flue gas within a predetermined distance of about 2.5 m of the flue gas pipeline measured from the outlet of the incinerator unit . The flue gas is cooled to a temperature of about 250 < 0 > C or less.

These special requirements are based on the IMO specification MEPC 244 (66), the standard specification for shipboard incinerators.

There are many useful devices for supplying pressurized air to a stream of water supplied directly to a flue gas pipeline. In the first device, the pressurized air is fed into the water stream as the water is discharged from the water discharge nozzle. In another useful device, pressurized air is supplied to the water stream before the water is discharged from the water discharge nozzle. In another alternative useful configuration, the pressurized air is supplied to the water stream after the water is discharged from the water discharge nozzle.

The flue gas pipeline preferably comprises a temperature measuring unit located in the flue gas pipeline at a distance from the outlet of the incinerator unit. This enables control of the temperature at the predetermined distance.

The predetermined distance is preferably about 2.5 m, so that it can meet the conventionally used standard.

The water injection mechanism of the inline cooling apparatus preferably includes flow rate control means for adjusting the flow rate of the water flow based on the temperature measured by the temperature measurement unit. This allows the cooling to be controlled according to the parameters of the flue gas.

The pressurized air supply connection portion of the inline cooling apparatus has pressure control means for regulating the pressure of the pressurized air based on the temperature measured by the temperature measurement unit. This allows cooling to be adjusted according to flue gas parameters.

Preferably, both the flow rate control means and the pressure control means can be used to optimally control the flue gas cooling, taking into account the desired temperature of the flue gas at a predetermined distance from the outlet of the incinerator unit.

Another aspect of the marine vessel waste treatment facility is disclosed in claims 2 to 8 and another advantageous feature of the flue gas cooling method in the marine vessel waste treatment facility is disclosed in claims 9 to 16.

An advantage of the present invention is that no auxiliary cooling reactor is required. It is also sufficient to install a technically simple cooling device and a temperature measuring device in the flue gas pipeline. This means that as a technically advantageous and inexpensive means, there is no need for additional space for mounting on marine vessels.

In the following, the present invention will be described by way of example with reference to the accompanying schematic drawings.
1 and 2 show a first embodiment of the present invention.
3 and 4 show a second embodiment of the present invention.
5 and 6 show a third embodiment of the present invention.

1 to 6, the garbage disposal facility of the marine vessel V is indicated by reference numeral 1. The waste disposal facility 1 is installed on the marine vessel V as shown in Figs. 1, 3 and 5.

The garbage to be treated in the garbage disposal facility 1 of the marine vessel V is usually composed of a mixture of dry garbage and wet garbage. In general, dry garbage according to IMO (International Maritime Organization) standards consists of about 40% cardboard, 30% other packaging and paper, 20% fiber and 10% plastic. Generally, wet trash consists of food waste and sludge with a maximum moisture content of about 80%. In order to efficiently burn the garbage mixture in the incinerator unit, the average moisture content of the garbage mixture should be maintained at about 50% or less.

Figs. 1 and 2 show a first embodiment of the present invention, Figs. 3 and 4 show a second embodiment of the present invention, Figs. 5 and 6 show a third embodiment of the present invention Respectively. Typically, the above three embodiments comprise similar arrangements, the main difference being the cooling device provided to the waste treatment facility, which will be described in detail below separately.

The main components of the garbage disposal facility 1 include a garbage receiving unit 2, a garbage supply unit 3, and an incinerator unit 4. The flue gas generated by the incineration of waste in the incinerator unit 4 is discharged from the discharge port 7 of the incinerator unit 4 to the flue gas pipeline 8. The flue gas pipeline 8 is connected directly to the outlet 7 of the incinerator unit 4.

The incinerator unit 4 may comprise a second combustion chamber 6 having a flue gas channel 5 arranged in front of the actual outlet 7 of the incinerator unit 4. The waste mixture is combusted in the incinerator unit 4, and the flue gas produced by the combustion of the waste or waste mixture is discharged through the outlet 7 to the flue gas pipeline 8. When the incinerator unit 4 includes the second combustion chamber 6, since the additional combustion step proceeds in the second combustion chamber 6, it is possible to separate the fly ash in a high ratio, Perfect combustion is possible. This arrangement prolongs the gas residence time and achieves very clean combustion. The first part of the incinerator unit 4 and of the second combustion chamber 6 is preferably connected by the flue gas channel 5. Preferably, the flue gas pipeline 8 is provided with a blower 9 for increasing the flue gas discharge efficiency.

The waste disposal facility 1 of the marine vessel V has an inline cooling device 10 connected to the flue gas pipeline 8 for effectively cooling the flue gas of the flue gas pipeline 8 . The inline cooling apparatus 10 further comprises a water discharge nozzle 12 for supplying a water stream directly into the flue gas pipeline 8 at a predetermined position A of the flue gas pipeline 8, And an injection mechanism (11). The water injection mechanism 11 is directly connected to the casing 81 of the flue gas pipeline 8 so that the water discharge nozzle 12 is located in the casing 81, 8) and can directly supply the water with the flue gas flowing.

The water injection mechanism 11 receives a line pressure of water from a water source 13 mounted on a marine vessel V and the line pressure is typically about 4 bar and is generally from a marine vessel Available levels. Between the water injection mechanism 11 and the water supply source 13, there is a flow rate control means 14 for controlling and controlling the flow rate of water.

In addition, the cooling device 10 is configured to cool the water into the water when the water is discharged from the water discharge nozzle 12 (FIGS. 1 and 2), into the water when the water flows through the water injection mechanism 3 and 4), or a pressurized air injection mechanism 16 for supplying pressurized air into the water after the water is discharged from the water injection mechanism 12 (FIGS. 5 and 6).

The pressurized air is supplied from the pressurized air supply source (17) mounted on the marine vessel (V) to the pressurized air injection mechanism (16). A pressure control unit 18 is provided between the pressurized air supply source 17 and the pressurized air injection mechanism 16. The pressurized air used in this cooling system is pressurized air which can normally be used in a machine room on a marine vessel.

The flue gas pipeline 8 is provided with a temperature measurement unit 20 at a predetermined distance D from the outlet 7 of the incinerator unit 4. The predetermined distance is about 2.5 m or less as described above. The flow rate of water is controlled and adjusted based on the temperature measured by the temperature measurement unit 20 as shown by the dotted lines in Figs. The pressure of the pressurized air is controlled and adjusted based on the temperature measured by the temperature measurement unit 20 as shown by the dotted lines in Figs. By optimizing the flow rate of the water and the pressure of the pressurized air, the desired degree of cooling, i.e. the flue gas temperature of the flue gas pipeline 8 at a predetermined distance of about 2.5 m from the outlet 7 of the incinerator unit 4, It is possible to achieve cooling to 250 DEG C or less.

In the embodiment of Figures 1 and 2, the water injection mechanism 11 has a channel for water flow from the water source 13 and a double hollow jacket surrounding the water injection mechanism. The pressurized air injection mechanism 16 is connected directly to the inside of the hollow jacket of the water injection mechanism 11 from the side of the water injection mechanism 11 so that pressurized air is injected into the hollow jacket and along the hollow jacket, (12) and allows the pressurized air to meet the stream of water as it is discharged from the water discharge nozzle (12) into the flue gas flowing in the flue gas pipeline (8). The pressurized air may be supplied to the water discharge nozzle 12 through a separate pipe, for example.

In the embodiment of Figures 3 and 4, the water injection mechanism 11 has a channel for water flow from the water source 13 and a jacket surrounding the water injection mechanism. The pressurized air injecting mechanism 16 penetrates the jacket from the side of the water injecting mechanism 11 and is directly connected to the channel of the water so that water flows along the channel from the water discharge nozzle 12 to the flue gas pipeline 8 The flue gas is introduced into the water stream before the water is discharged.

In the embodiment of Figures 5 and 6, the water injection mechanism 11 has a channel for water flow from the water source 13 and a jacket surrounding the water injection mechanism. Since the pressurized air injecting mechanism 16 is connected directly to the casing 81 of the flue gas pipeline 8 separately from the water injecting mechanism 11 in the present embodiment, Is located in the casing (8). The pressurized air injection mechanism 16 is installed close to the discharge nozzle 12 of the water injection mechanism 11. In this way, after the water is discharged from the discharge nozzle 12 into the flue gas flowing in the flue gas pipeline 8, the pressurized air is directly supplied to the water.

In all three embodiments, the pressurized air supplied to the water stream disperses water into mist, which is discharged from the outlet 7 of the incinerator unit 4 to a predetermined It has the largest surface for cooling the flue gas in the distance. The flue gas is cooled to a temperature of about 250 ° C or less.

The drawings and the related description are only for clarifying the basic idea of the present invention. The present invention may be modified in detail within the scope of the following claims.

Claims (16)

At least one waste incinerator unit (4) having at least one waste storage unit (2), at least one waste supply unit (3), an outlet (7) and at least one flue gas 1. A waste disposal facility (1) for a marine vessel (V) comprising a flue gas pipeline (8)
The at least one flue gas pipeline 8 comprises an inline cooling device 10 for cooling the discharged flue gas to a predetermined temperature and the inline cooling device 10 comprises a water stream A water injection mechanism 11 having a water discharge nozzle 12 for direct supply to the flue gas pipeline 8 and a pressurized air injection mechanism 16 for supplying pressurized air into the water flow Waste disposal facilities for marine vessels. The method according to claim 1,
Characterized in that the pressurized air injection mechanism (16) is connected to the water injection mechanism (11) so that pressurized air is supplied into the water stream when water is discharged from the water discharge nozzle (12) . The method according to claim 1,
Characterized in that the pressurized air injection mechanism (16) is connected to the water injection mechanism (11) so that pressurized air is supplied into the water stream before water is discharged from the water discharge nozzle (12) . The method according to claim 1,
Characterized in that the pressurized air injection mechanism (16) is connected to the flue gas pipeline (8) so that pressurized air is supplied into the water stream after the water is discharged from the water discharge nozzle (12) equipment. 12. A compound according to any one of the preceding claims,
Characterized in that the flue gas pipeline (8) comprises a temperature measuring unit (20) located in a flue gas pipeline (8) a predetermined distance (D) away from the outlet of the incinerator unit (4) Waste disposal facilities. 12. A compound according to any one of the preceding claims,
Wherein the predetermined distance (D) is about 2.5 m. 12. A compound according to any one of the preceding claims,
Characterized in that the water injection mechanism (11) comprises a flow rate control means (14) for controlling the flow rate of the water flow based on the temperature measured by the temperature measurement unit (20) equipment. 12. A compound according to any one of the preceding claims,
Characterized in that the pressurized air injection mechanism (16) comprises pressure control means (18) for adjusting the pressure of the pressurized air based on the temperature measured by the temperature measurement unit (20) Waste disposal facilities. At least one waste incinerator unit (4) having at least one waste storage unit (2), at least one waste supply unit (3), an outlet (7) and at least one flue gas pipe A flue gas cooling method in a waste disposal facility (1) of a marine vessel (V) comprising a line (8), said flue gas being discharged into said flue gas pipeline (8)
The flue gas in the flue gas pipeline 8 is cooled to a predetermined temperature by the inline cooling device 10 and the water stream is led by the inline cooling device 10 through the water discharge nozzle 12 Characterized in that the flue gas is directly fed into the flue gas pipeline (8) and also the pressurized air is fed into the water stream by the inline cooling device (10) Cooling method. 10. The method of claim 9,
Wherein the pressurized air is supplied into the water stream when water is discharged from the water discharge nozzle (12). 10. The method of claim 9,
Wherein the pressurized air is supplied into the water stream before the water is discharged from the water discharge nozzle (12). 10. The method of claim 9,
Wherein the pressurized air is supplied into the water stream after the water is discharged from the water discharge nozzle (12). 13. The method according to any one of claims 9 to 12,
Characterized in that the temperature of the flue gas in the flue gas pipeline (8) is measured at a predetermined distance (D) from the outlet (7) Gas cooling method. 14. The method according to any one of claims 9 to 13,
Characterized in that the flow rate of the water stream is regulated on the basis of the measured temperature of the flue gas. 15. The method according to any one of claims 9 to 14,
Wherein the pressure of the pressurized air is regulated on the basis of the measured temperature of the flue gas. 16. The method according to any one of claims 9 to 15,
Wherein the flue gas is cooled to a predetermined temperature of about 250 DEG C or less when the flue gas reaches a predetermined distance (D) from the discharge port (7). The flue gas cooling Way.

Images