KR102394412B1 - Collection device with increased collection efficiency of ash and removal efficiency of collected ash - Google Patents

Abstract

The present invention relates to an ash collection probe 100 that is connected to a measurement target facility (S) that is a target to collect ash, and delivers flue gas and ash from the measurement target facility (S); The ash collection probe 100 is connected and , an ash collection chamber 200 comprising a filter 240 positioned inwardly; and an exhaust gas condenser 300 connected to the ash collection chamber 200 to deliver the exhaust gas; Including, the filter 240 relates to a collection system, including a mesh network forming a side surface and a lower surface.

Description

Collection device with increased collection efficiency of ash and removal efficiency of collected ash

The present invention relates to a collection device with increased ash collection efficiency and increased ash removal efficiency.

Recently, environmental regulations for thermal power plants have become stricter, and in particular, regulations related to fine dust are getting stricter.

In the case of solid combustion devices including coal-fired power plants and incinerators, fine dust is generated from coal-fired power plants and incinerators, but there is a problem of primary fine dust emitted directly and secondary fine dust emitted indirectly by NOx and SOx. becomes

Since fine dust is generated by the generation of volatile and nonvolatile substances contained in the ash exposed to combustion and high temperature, it is important to remove the ash from the solid combustion device.

Conventionally, a device for collecting ash from a device that generates ash, including an incinerator, has been developed, but the awareness for easily removing the collected ash was insufficient, and the awareness to increase the ash collection efficiency was insufficient.

For example, Korean Patent Document No. 10-1285557 relates to a fly ash collecting system for analyzing the composition of fly ash, and collects fly ash in real time using a collecting unit. However, in such a system, there is no awareness to increase the ash collection efficiency,

For another example, Korean Patent Document No. 10-1923502 relates to an exhaust gas purification method and an exhaust gas purification system by the same. The washing water is supplied through the washing water supply pipe connected to the However, in such a system, there was no awareness of the easy removal of the filter, the lack of awareness for easily removing the collected ash, and the lack of awareness to increase the ash collection efficiency.

(Patent Document 1) Korean Patent Document No. 10-1285557

(Patent Document 2) Korean Patent Document No. 10-1923502

The present invention has been devised to solve the above problems.

Specifically, the present invention forms the ash collection chamber in a separable structure so that the collected ash can be easily removed, so that the ash collection chamber can be reused, and the amount of fine dust generated is analyzed by accurately measuring the amount of ash collected. to do

In addition, the present invention is to form the exhaust gas condenser in a separable structure, to easily remove the condensed moisture and to reuse the exhaust gas condenser.

In addition, the present invention is to form the ash collection probe in a separable structure to reuse the ash collection probe.

In addition, the present invention is to increase the ash collection efficiency by increasing the contact area between the filter and the exhaust gas in the ash collection chamber.

In addition, the present invention is to increase the life of the filter by configuring the flow path to use the multiple surfaces of the filter in the ash collection chamber.

In addition, the present invention is to collect ash even in a high temperature environment using a metal filter.

In addition, the present invention is to connect the collection system to the measurement target facility at a desired location to easily collect the ash of the measurement target facility.

In addition, the present invention is to connect the collection system to the equipment to be measured, to collect the ash of the equipment to be measured in real time.

In addition, the present invention is for the control unit to receive ash data based on the ash collected by the collection system and to optimally operate the collection system based on the received ash data.

An embodiment of the present invention for solving the above problems is connected to a measurement target facility (S) that is a target to collect ash, and an ash collection probe ( 100); an ash collection chamber 200 connected to the ash collection probe 100 and including a filter 240 positioned inside; and an exhaust gas condenser 300 connected to the ash collection chamber 200 to deliver the exhaust gas; Including, the filter 240 relates to a collection system, including a mesh network forming a side surface and a lower surface.

In one embodiment, the ash collection chamber 200 includes: an exhaust gas inlet 210 connected to the ash collection probe 100; and an exhaust gas outlet 220 connected to the exhaust gas condenser 300; The filter 240 is located inside the ash collection chamber 200, and is spaced apart from the inner wall of the ash collection chamber 200, the exhaust gas inlet 210, and the exhaust gas outlet 220. can do.

In one embodiment, the filter 240 has a passage 241 formed therein, and the ash collection chamber 200 has one side communicating with the exhaust gas outlet 220 , and the other side of the passage 241 . It may further include an extension member 221 located on the inside.

In one embodiment, the exhaust gas condenser 300 includes an exhaust gas inlet 310 connected to the ash collection chamber 200; an exhaust gas outlet in communication with the vacuum pump 500; a condensing vessel 340 located inside the exhaust gas condenser 300 and communicating with the exhaust gas inlet 310 and the exhaust gas outlet 320; and a heat exchanger 350 located on the outer surface of the condensing vessel 340; may include

In one embodiment, the condensing vessel 340 includes a first condensing vessel 341; and a second condensing vessel 342 positioned to be spaced apart from the first condensing vessel 341, wherein the exhaust gas condenser 300 is connected to the exhaust gas inlet 310, and from the exhaust gas inlet 310 a first connection line 361 extending to the first condensing vessel 341; a second connection line (362) extending from the first condensing vessel (341) to the second condensing vessel (342); and a third connection line 363 connected to the exhaust gas outlet 320 and extending from the flue gas outlet 320 to the second condensing vessel 342; may include

In one embodiment, the ash collection chamber 200 includes an upper chamber and a lower chamber, a first flange 231 is located on one side of the upper chamber, and a second flange 232 is located on one side of the lower chamber. located, the first flange 231 and the second flange 232 may be detachably coupled.

In one embodiment, the exhaust gas condenser 300 includes an upper condenser and a lower condenser, a first flange 331 is located on one side of the upper condenser, and a second flange 332 is located on one side of the lower condenser. , the first flange 331 and the second flange 332 may be detachably coupled.

In one embodiment, the ash collection probe 100 includes a first probe and a second probe, a first flange 131 is positioned on one side of the first probe, and a second flange on one side of the second probe 132 is positioned, and the first flange 131 and the second flange 132 may be detachably coupled.

In one embodiment, the condensing vessel 340 has a drain hole 344 formed at an upper side, coupled to the exhaust gas condenser 300, and a support member 343 coupled to the condensing vessel 340; may include

In one embodiment, a vacuum pump 500 communicating with the exhaust gas condenser 300 and flowing the exhaust gas and ash in the measurement target facility S to the ash collection probe 100; may include

In one embodiment, a flow meter 400 connected to the vacuum pump 500 to control the flow rates of ash and exhaust gas transferred from the measurement target facility (S) to the ash collection probe 100; may further include.

In one embodiment, the ash collection chamber 200 may further include a vibrator 250 formed on its outer surface.

An embodiment may include a control unit 600 for monitoring the temperature and reaction time of the collection system.

In one embodiment, the filter 240 may be a metal filter.

According to the present invention, the following effects are achieved.

The present invention forms the ash collection chamber in a separable structure so that the collected ash can be easily removed, so that the ash collection chamber can be reused, and the amount of fine dust generated can be analyzed by accurately measuring the amount of ash collected. .

In addition, the present invention forms the exhaust gas condenser in a separable structure, so that the condensed moisture can be easily removed and the exhaust gas condenser can be reused.

In addition, the present invention forms the ash collection probe in a detachable structure, so that the ash collection probe can be reused.

In addition, the present invention can increase the ash collection efficiency by increasing the contact area between the filter and the exhaust gas in the ash collection chamber.

In addition, the present invention configures the flow path to use multiple surfaces of the filter in the ash collection chamber, thereby increasing the lifespan of the filter.

In addition, the present invention can collect ash even in a high-temperature environment by using a metal filter.

In addition, according to the present invention, it is possible to easily collect the ash of the equipment to be measured by connecting the collection system to the equipment to be measured at a desired location.

In addition, according to the present invention, by connecting the collection system to the equipment to be measured, it is possible to collect the ash of the equipment to be measured in real time.

In addition, according to the present invention, the control unit may receive ash data based on the ash collected by the collection system and optimally operate the collection system based on the received ash data.

1 is a schematic diagram showing a ash collection system according to the present invention. .
2 is a view for explaining the ash collection probe according to the present invention.
3 is a view for explaining the ash collection chamber according to the present invention.
4 is a view for explaining a filter according to the present invention.
5 and 6 are views for explaining the exhaust gas condenser according to the present invention.

In some cases, well-known structures and devices may be omitted or shown in block diagram form focusing on core functions of each structure and device in order to avoid obscuring the concept of the present invention.

In addition, in the description of the embodiments of the present invention, if it is determined that a detailed description of a well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, the terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification.

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

1 to 6, a configuration according to the present invention will be described.

The collection system according to the present invention includes a ash collection probe 100 , an ash collection chamber 200 , an exhaust gas condenser 300 , a flow meter 400 , a vacuum pump 500 , and a control unit 600 .

1 and 2, the ash collection probe 100 will be described.

The ash collection probe 100 is connected to a measurement target facility (S) that is a target to measure ash, and ash and exhaust gas are delivered from the measurement target facility (S).

In the ash collection probe 100 , the flow rates of exhaust gas and ash delivered from the measurement target facility S may vary according to a flow meter 400 and a vacuum pump 500 to be described later. This will be described later.

The ash collection probe 100 may be connected to the ash collection chamber 200 to be described later to deliver ash and exhaust gas to the ash collection chamber 200 .

The ash collection probe 100 may provide a path through which ash may move from the measurement target facility S to the ash collection chamber 200 .

The ash collection probe 100 may be inserted into the measurement target facility S to receive ash and exhaust gas from the measurement target facility S, but is not limited thereto.

The ash collection probe 100 may determine the degree of insertion into the measurement target facility S, including the scale.

The ash collection probe 100 may include a first probe and a second probe, and the first probe and the second probe may be coupled by a flange 130 to be described later. This will be described later.

At this time, although the first probe and the second probe are formed on the left and right sides of FIG. 2 , respectively, the present invention is not limited thereto.

The ash collection probe 100 may include a temperature sensor 110 , a valve 120 , and a flange 130 .

The temperature sensor 110 may be formed on the ash collection probe 100 to measure the temperature of the delivered exhaust gas.

The valve 120 may be formed on the ash collection probe 100 to open and close the ash collection probe 100 . That is, the valve 120 may block the ash collection probe 100 , thereby blocking the movement of exhaust gas and ash to the ash collection chamber 200 to be described later.

For example, the valve 120 may be blocked in consideration of an inflow amount of exhaust gas and ash or a temperature on the ash collection probe 100 , but is not limited thereto.

At this time, the valve 120 may be opened and closed manually, but is not limited thereto, and may be opened and closed automatically according to the control of the controller 600 to be described later.

The flange 130 may detachably couple the first probe and the second probe.

In this case, the flange 130 may be formed at the rear end of the temperature sensor 110 and the valve 120 described above, but is not limited thereto.

The flange 130 includes a first flange 131 and a second flange 132 .

The first flange 131 is formed on one side of the first probe, the second flange 132 is formed on one side of the second probe, and the first flange 131 and the second flange 132 are detachably from each other. are combined

Accordingly, since the ash collection probe 100 can be separated, accumulated ash can be easily removed without flowing from the ash collection probe 100 to the ash collection chamber 200 , and the ash collection probe 100 . can be reused.

At this time, the first flange 131 and the second flange 132 have been described as being flange-coupled to each other, but the present invention is not limited thereto.

3 and 4, the ash collection chamber 200 will be described.

The ash collection chamber 200 may be connected to the ash collection probe 100 to receive ash and exhaust gas to collect ash.

The ash collection chamber 200 may be connected to an exhaust gas condenser 300 to be described later to deliver the exhaust gas.

The ash collection chamber 200 may include an exhaust gas inlet 210 , an exhaust gas outlet 220 , a flange 230 , a filter 240 , and a vibrator 250 .

The exhaust gas inlet 210 is formed at the front end of the ash collection chamber 200 and is connected to the ash collection probe 100 . The flue gas inlet 210 delivers ash and flue gas to the inside of the ash collection chamber 200 .

The exhaust gas outlet 220 is formed at the rear end of the ash collection chamber 200 and is connected to the exhaust gas condenser 300 to be described later. The flue gas outlet 220 delivers the flue gas flowing through the ash collection chamber 200 to the flue gas condenser 300 .

The exhaust gas outlet 220 may be connected to the extension member 221 .

The extension member 221 is a member extending from the exhaust gas outlet 220 to the passage 241 of the filter 240 to be described later. One side of the extension member 221 communicates with the exhaust gas outlet 220 , and is located inside the passage 241 .

The extension member 221 is located on the upper side of the passage 241 of the filter 240, and the exhaust gas and ash introduced from the exhaust gas inlet 210 initially block the flow to the passage 241 of the filter 240. and may form a flow path to flow along the outside of the filter 240 and flow to the passage 241 .

Accordingly, the exhaust gas and ash introduced from the exhaust gas inlet 210 can sufficiently contact the filter 240 and can evenly contact the surface of the filter 240, so that the ash collection of the filter 240 can be sufficiently performed. and the lifespan of the filter 240 may be increased.

At this time, the exhaust gas outlet 230 and the extension member 221 may be formed as a single member rather than being formed as separate members.

At this time, a member for covering the upper surface may be further formed on the upper surface of the filter 240 to prevent the exhaust gas flowing through the exhaust gas inlet 210 from flowing, but is not limited thereto.

The flange 230 is formed to separate one end and the other end of the ash collection chamber 200 , and couples the ash collection chamber 200 .

At this time, the flange 230 may separate the upper and lower sides of the ash collection chamber 200, but is not limited thereto.

The flange 230 includes a first flange 231 formed on one surface of the ash collection chamber 200 and a second flange 232 formed on the other surface of the ash collection chamber 200 to be coupled to the first flange 231 . includes

The first flange 231 and the second flange 232 may be separated to separate the first chamber and the second chamber, and the filter 240 may be removed to remove the collected ash, the ash collection chamber ( 200), the ash can be easily removed when removing the collected ash.

At this time, the first flange 231 and the second flange 232 may be flange-coupled to each other, but is not limited thereto. For example, another method may be a clamp method.

The filter 240 is positioned inside the ash collection chamber 200 and includes a mesh network forming a side surface and a lower surface.

The filter 240 may be located in the ash collection chamber 200 to collect ash.

The filter 240 may be positioned to be spaced apart from the inner wall of the ash collection chamber 200 , the exhaust gas inlet 210 , and the exhaust gas outlet 220 .

Accordingly, the exhaust gas may come into contact with the front surface of the filter 240 and ash may be collected by the filter 240 .

The filter 240 may have a passage 241 formed therein, and the aforementioned extension member 221 may be inserted therein.

In this case, the passage 241 of the filter may have a size corresponding to the diameter of the extension member 221 .

At this time, the filter 240 may be formed of a metal material to collect ash even in a high temperature environment, but is not limited thereto.

The vibrator 250 is positioned on the outer surface of the ash collection chamber 200 to vibrate the ash collection chamber 200 .

The vibrator 250 vibrates the ash collection chamber 200 to separate the ash attached to the filter 240 from the filter 240 . The separated ash falls to the lower side of the ash collection chamber 200 . Thereafter, by removing the flange 230 , the ash collected in the ash collection chamber 200 may be recovered.

Referring to FIG. 3B , the flue gas and ash flow from the flue gas inlet 210 to the ash collection chamber 200 and flow to the flue gas outlet 220 .

As described above, when the extension member 221 is formed, the exhaust gas and ash introduced from the exhaust gas inlet 210 flow between the ash collection chamber 200 and the filter 240 or to the outside of the extension member 221 . can move

The exhaust gas and ash flowing between the ash collection chamber 200 and the filter 240 may flow into the extension member 221 along the passage 241 of the filter 240 , and discharged through the exhaust gas outlet 220 . can be

The exhaust gas and ash flowed to the outside of the extension member 221 flows between the ash collection chamber 200 and the filter 240 , and then flows into the extension member 221 along the passage 241 of the filter 240 . It may be, and may be discharged through the exhaust gas outlet (220).

At this time, the ash flows between the filters 240 , and is collected by the filter 240 , and discharged through the exhaust gas outlet 220 may be exhaust gas from which ash has been removed.

The exhaust gas condenser 300 condenses moisture in the exhaust gas.

Since the bar includes the exhaust gas condenser 300 , ash can be collected even in a high-temperature environment, and the exhaust gas condenser 300 is connected to the rear end of the ash collection chamber 200 , but is not limited thereto.

The exhaust gas condenser 300 may include a first condenser and a second condenser, and the first condenser and the second condenser may be coupled by a flange 330 to be described later. This will be described later.

The exhaust gas condenser 300 includes an exhaust gas inlet 310 , an exhaust gas outlet 320 , a flange 330 , a condensing vessel 340 , a heat exchanger 350 , and a connection line 360 .

The flue gas inlet 310 is connected to the ash collection chamber 200 and the flue gas flows into the flue gas condenser 300 .

The exhaust gas outlet 320 communicates with the vacuum pump 500 .

The flange 330 is formed to separate one end and the other end of the exhaust gas condenser 300 , and is coupled to the exhaust gas condenser 300 .

At this time, the flange 330 may separate the upper side and the lower side of the exhaust gas condenser 300, but is not limited thereto.

The flange 330 includes a first flange 331 formed on one surface of the exhaust gas condenser 300 and a second flange 332 formed on the other surface of the exhaust gas condenser 300 to be coupled to the first flange 331. .

Accordingly, since the exhaust gas condenser 300 can be separated, moisture condensed in the exhaust gas condenser 300 can be easily removed, and the exhaust gas condenser 300 can be reused.

At this time, the first flange 331 and the second flange 332 may be flange-coupled to each other, but is not limited thereto. For example, another method may be a clamp method.

The condensing vessel 340 is a vessel in which the exhaust gas flows and is condensed. A connection line 360 to be described later may be coupled to the condensation container 340 .

A coupling hole 345 corresponding to the diameter of the connection line 360 may be formed in the condensation container 340 to be coupled to the connection line 360 . The connection line 360 may be coupled through the coupling hole 345 and separated from the condensation vessel 340 through the coupling hole 345 .

In this case, the number of coupling holes 345 may vary depending on the number of connection lines 360 , and the number of the coupling holes 345 is not limited to the illustrated position and size.

The condensing vessel 340 may include one or more condensing vessels 340, and may include a first condensing vessel 341 and a second condensing vessel 342, but this will be described later. Condensation vessel ( 340 may be supported by the exhaust gas condenser 300 by the support member 343 .

The support member 343 is formed so that the condensation container 340 can be coupled according to the number of the condensation containers 340 , and can be fitted around the inner circumference of the exhaust gas condenser 300 , and if necessary, the support member 343 . may be separated from the exhaust gas condenser 300 .

Therefore, when the support member 343 is separated from the exhaust gas condenser 300 , the condensation container 340 can be separated together, so it is convenient to separate the condensation container 340 .

A drain hole 344 may be formed at the upper end of the condensation container 340 , so that moisture condensed in the exhaust gas may be discharged from the condensation container 340 .

At this time, the size, position, and number of the drain holes 344 are not limited to the illustrated bar.

The heat exchanger 350 is located on the outer surface of the condensing vessel 340, and is formed so that the coolant flows in and then out.

The exhaust gas flowing in the condensing vessel 340 may be heat exchanged in the heat exchanger 350, so that the high temperature exhaust gas may be condensed.

The condensed flue gas may fall to the bottom of the condensing vessel 340 .

At this time, the heat exchanger 350 is not limited to the size shown.

At this time, the condensation container 340 may be made of glass to maximize the heat transfer effect, but is not limited thereto.

Referring to FIG. 5(b), a case in which the condensing vessel 340 is formed in two as a first condensing vessel 341 and a second condensing vessel 342 will be described.

The connection line 360 is a flow path through which the exhaust gas flows, and the connection line 360 may include a first connection line 361 , a second connection line 362 , and a third connection line 363 .

The first connection line 361 may be connected to the exhaust gas inlet 310 and extend to the lower end of the first condensation vessel 341 . The exhaust gas may flow into the first condensing vessel 341 through the first connection line 361 , and then flow into the second connection line 362 .

The second connection line 362 connects the first condensing vessel 341 and the second condensing vessel 342 , and extends from the upper end of the first condensing vessel 341 to the lower end of the second condensing vessel 342 . can be

The exhaust gas may move from the first condensing vessel 341 to the second condensing vessel 342 through the second connection line 362 .

The third connection line 363 is connected to the exhaust gas outlet 320 and may extend to the lower end of the second condensation vessel 342 .

The exhaust gas moved to the second condensing vessel 342 through the second connection line 362 may move to the exhaust gas outlet 320 through the third connection line 363 .

At this time, one connection line 360 may be formed to be greater than the number of the condensing vessels 340 according to the number of the condensing vessels 340 , but is not limited thereto.

At this time, two coupling holes 345 are respectively formed in the first condensing vessel 341 and the second condensing vessel 342 , one end of the first connecting line 361 and the second connecting line 362 , respectively. Both ends are coupled to one end of the third connection line 363 .

The flow meter 400 is a device capable of measuring a flow rate and is connected to the exhaust gas condenser 300 .

The flow meter 400 is connected to a vacuum pump 500 to be described later to control the flow rates of exhaust gas and ash transferred from the measurement target facility S to the ash collection probe 100 .

The vacuum pump 500 is a pump for flowing the exhaust gas and ash in the measurement target facility S to the ash collection probe 100 .

The vacuum pump 500 communicates with the exhaust gas condenser 300 and may communicate with the measurement target facility (S).

At this time, the vacuum pump 500 is located at the rear end of the exhaust gas condenser 300, and since moisture in the exhaust gas is separated from the exhaust gas condenser 300, the life of the vacuum pump 500, which is vulnerable to moisture, can be secured.

The vacuum pump 500 may be connected to the above-described flow meter 400 to adjust the flow rates of the exhaust gas and ash flowing to the ash collection probe 100 .

At this time, the vacuum pump 500 is located at the rear end of the flow meter 400 , but is not limited thereto, and may be connected to a facility for processing the exhaust gas at the rear end of the vacuum pump 500 .

At this time, the vacuum pump 500 can flow the exhaust gas and ash from the measurement target facility S to the ash collection probe 100 at a desired time, and the collection device according to the present invention can collect the ash in real time. there is.

The control unit 600 may monitor the temperature and reaction time of the collection system, and the user may check the real-time ash collection degree of the collection system, the temperature of the exhaust gas, and the like, from the control unit 600 .

A process in which ash is collected using the collection system according to the present invention will be described.

Insert the ash collection probe 100 into the measurement target equipment (S).

The vacuum pump 500 communicates with the measurement target facility S, and guides the exhaust gas to the ash collection probe 100 .

The flow rate of the exhaust gas may be controlled by adjusting the operation and degree of operation of the vacuum pump 500 based on the flow rate of the exhaust gas flowing from the flow meter 400 to the ash collection probe 100 .

The exhaust gas is transferred from the ash collection probe 100 to the ash collection chamber 200 , and a filter 240 is positioned in the ash collection chamber 200 to collect ash in the exhaust gas.

In the ash collection chamber 200 , the ash attached to the filter 240 is separated by the operation of the vibrator 250 and may be positioned as the ash collection chamber 200 .

Ash may be removed by removing the flange 230 from the ash collection chamber 200 .

The exhaust gas from which the ash has been removed may be condensed in the exhaust gas condenser 300 and then discharged to the outside.

Ash in the flue gas can be collected through the process as described above.

At this time, the controller 600 receives ash data on the amount of ash collected in the ash collection chamber 200 and the operating conditions of the vibrator 250 , and the controller 600 controls the collection system based on the ash data. can do.

In the above, the present invention has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but these are merely exemplary, and those skilled in the art can make various modifications and equivalents from the embodiments of the present invention. It will be appreciated that embodiments are possible. Therefore, the protection scope of the present invention should be defined by the claims.

100: ash collection probe
110: temperature sensor
120: valve
130: flange
131: first flange
132: second flange
200: ash collection chamber
210: flue gas inlet
220: exhaust gas outlet
221: extension member
230: flange
231: first flange
232: second flange
240: filter
241: passage
250: vibrator
300: flue gas condenser
310: flue gas inlet
320: exhaust gas outlet
330: flange
331: first flange
332: second flange
340: condensing vessel
341: first condensing vessel
342: second condensing vessel
343: support member
344: drain hole
345: coupling hole
350: heat exchanger
360: connecting line
361: first connection line
362: second connection line
363: third connection line
400: flow meter
410: flue gas inlet
420: exhaust gas outlet
500: vacuum pump
510: flue gas inlet
520: exhaust gas outlet
600: control unit
S: Equipment to be measured

Claims (14)

The ash collection probe 100 is connected to the measurement target facility (S) that is a target to collect ash, the exhaust and ash are delivered from the measurement target facility (S);
an ash collection chamber 200 connected to the ash collection probe 100 and including a filter 240 positioned inside; and
an exhaust gas condenser 300 connected to the ash collection chamber 200 to deliver the exhaust gas; including,
The filter 240 includes a mesh network forming a side surface and a lower surface,
The exhaust gas condenser 300,
upper and lower condensers;
a first flange 331 positioned at one side of the upper condenser;
a second flange 332 positioned at one side of the lower condenser and fastened to the first flange 331;
an exhaust gas inlet 310 connected to the ash collection chamber 200;
an exhaust gas outlet 320 communicating with the exhaust gas inlet 310;
As a condensation vessel 340 located inside the exhaust gas condenser 300 and communicating with the exhaust gas inlet 310 and the exhaust gas outlet 320, a first condensing vessel 341 and the first condensing vessel 341 ) and a second condensing vessel (342) positioned spaced apart, comprising a condensing vessel (340);
a heat exchanger 350 positioned on the outer surface of the condensing vessel 340;
It is connected to the exhaust gas inlet 310, and from the exhaust gas inlet 310
a first connection line 361 extending to the first condensing vessel 341;
a second connection line (362) extending from the first condensing vessel (341) to the second condensing vessel (342); and
and a third connection line 363 connected to the exhaust gas outlet 320 and extending from the flue gas outlet 320 to the second condensing vessel 342,
The condensing vessel 340,
a drain hole 344 located above each of the first condensation container 341 and the second condensation container 342; and
It is coupled to the inside of the exhaust gas condenser 300, and includes a support member 343 to which each of the first condensation container 341 and the second condensation container 342 is coupled,
The exhaust gas is the first connection line 361 , the inner side of the first condensation vessel 341 , the second connection line 362 , the inner side of the second condensation vessel 342 , and the third connection line 363 ) flows sequentially and is cooled by the heat exchanger 350 to produce condensed water,
The generated condensate is collected in the first condensing vessel 341 and the second condensing vessel 342,
When the upper condenser is removed by releasing the coupling between the first flange 331 and the second flange 332 , and the support member 343 is removed, the first condensing vessel 341 and the second condensing vessel 342 are removed. ) is removed together with the support member 343, and condensed water can be discharged to the outside through the drain hole 344,
collection system.
The method of claim 1,
The ash collection chamber 200,
An exhaust gas inlet 210 connected to the ash collection probe 100; And
an exhaust gas outlet 220 connected to the exhaust gas condenser 300; further comprising,
The filter 240 is located inside the ash collection chamber 200, and is spaced apart from the inner wall of the ash collection chamber 200, the exhaust gas inlet 210, and the exhaust gas outlet 220.
collection system.
3. The method of claim 2,
The filter 240 has a passage 241 formed therein,
The ash collection chamber 200, one side communicates with the exhaust gas outlet 220, the other side of the extension member 221 positioned inside the passage 241; further comprising,
collection system.
delete delete 4. The method of claim 3,
The ash collection chamber 200 includes an upper chamber and a lower chamber,
A first flange 231 is located on one side of the upper chamber, and a second flange 232 is located on one side of the lower chamber,
The first flange 231 and the second flange 232 are detachably coupled,
collection system.
delete The method of claim 1,
The ash collection probe 100 includes a first probe and a second probe,
A first flange 131 is positioned on one side of the first probe, and a second flange 132 is positioned on one side of the second probe,
The first flange 131 and the second flange 132 are detachably coupled,
collection system.
delete According to claim 1,
a vacuum pump 500 communicating with the exhaust gas condenser 300 and flowing the exhaust gas and ash in the measurement target facility S to the ash collection probe 100; containing,
collection system.
11. The method of claim 10,
a flow meter 400 connected to the vacuum pump 500 to control the flow rates of ash and exhaust gas transferred from the measurement target facility (S) to the ash collection probe 100; further comprising,
collection system.
The method of claim 1,
The ash collection chamber 200 further includes a vibrator 250 formed on its outer surface,
collection system.
The method of claim 1,
Including a control unit 600 for monitoring the temperature and reaction time of the collection system,
collection system.
The method of claim 1,
The filter 240 is a metal filter,
collection system.

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