KR101947208B1 - Wireless Control Door Device for Flow Changeover Exhaust Gas Bypass of Heat Recovery Boiler - Google Patents

Abstract

The present invention provides a built-in bypass function for automatic control of a door for bypassing exhaust gas, thereby solving the difficulty of securing a space for installation, and more particularly, A first and a third space part formed by partitioning through first and second partition walls provided inside the boiler body; A water tube assembly installed in the first and third spaces; A shutoff door means installed between the boiler body and the hopper member for opening and closing the first to third space portions; The blocking door means includes a first blocking door disposed in a state blocking the first space portion, a second blocking door disposed in a state blocking the second space portion, and a third blocking door disposed in a state blocking the third space portion First to third slide rails respectively protruding from the inner bottom surface of the boiler body facing the bottom surfaces of the first to third blocking doors, first to third slide rails provided on the bottom surface of the first to third blocking doors, And first to third slide grooves respectively formed to be slidable in a manner that the rails are inserted into the first to third sliding doors, There is provided a radio control door apparatus for switching the exhaust gas bypass flow of a heat recovery boiler provided with third driving means.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a wireless control door device for switching an exhaust gas bypass flow of a heat recovery boiler,

The present invention relates to a wireless control door device for switching the exhaust gas bypass flow of a heat recovery boiler, and more particularly, to a wireless control door device for bypass control of a door for bypassing an exhaust gas, This makes it possible to solve the difficulty in securing a space for installation, and more particularly, to provide a convenience and prompt switching operation of the door due to the switching movement of the door for switching the flow of the exhaust gas.

As shown in FIGS. 1A and 2, the conventional heat recovery boiler 10 for recovering heat from the exhaust gas discharged from the boiler is constructed such that the steam produced on the upper surface of the boiler body 11 is stored and collected in one place A steam drum 12 is installed.

A water tube assembly 14 is installed in the internal space 13 of the boiler body 11 and a header 15 communicating with the water tube assembly 14 is connected to the steam drum 15 through a connection pipe 16. [ (12).

A hopper member 17 is fixed to one side of the boiler body 11 so as to communicate with the internal space portion 13. An exhaust gas supply pipe 18 is connected to the hopper member 17 .

One end of a bypass tube 19 connected in a branched form from an exhaust gas supply pipe 18 is connected to the exhaust gas supply pipe 18 and the other end of the bypass pipe 19 is connected to an exhaust pipe 20 connected to the boiler body 11 ).

The bypass tube 19 and the exhaust gas supply pipe 18 are respectively provided with first and second degree-of-adjustment dampers 21 and 22 for controlling opening and closing functions as well as opening and closing functions, respectively. The first and second opening control dampers 21 and 22 can control the amount of flow together with the switching of the flow direction of the exhaust gas through the operation of the first and second opening control dampers 21 and 22, The operation implementations are made opposite to each other.

For example, when the first degree-of-adjustment damper 21 installed in the bypass tube 19 performs the closing operation and the flow path of the bypass tube 19 is closed, the second degree-of-opening adjusting damper 22 is opened The exhaust gas is supplied to the inner space 13 of the boiler body 11 along the exhaust gas supply pipe 18 so that the exhaust gas supplied to the boiler body 11 is exhausted to the exhaust pipe 20 The process of escaping to the outside is performed.

At this time, a water tube assembly 14 in which water is circulated and supplied as described above is installed in the internal space portion 13 of the boiler body 11 to perform heat exchange between exhaust gas and water flowing to the water tube assembly 14 And steam is produced.

As a result, heat is exchanged between the water flowing into the water tube assembly 14 and the exhaust gas passing through the inner space 13, and steam is produced. The steam thus produced is collected in the steam drum 12 through the connection pipe 16, and the collected steam is supplied to the succeeding apparatus in which the steam is used.

Since the heat recovery boiler 10 constructed as above has the bypass tube 19 for bypassing the exhaust gas when the steam production is stopped, the heat recovery boiler 10 is provided outside the heat recovery boiler 10, When the recovery boiler 11 is to be installed, there is a restriction that it is necessary to secure a sufficient installation space occupied by the bypass tube 19 at a place where the recovery boiler 11 is to be installed. In addition, there is also a problem that the amount of work due to the installation is increased due to the increase in the material and production cost due to the installation of the bypass tube 19.

The first and second opening degree adjusting dampers 21 and 22 are installed inside the bypass tube 19 and the exhaust gas supply pipe 18 as described above. The workability according to the work is not easy and the installation structure is also complicated, resulting in a problem of lowering work efficiency and productivity.

Particularly, when the first and second opening degree adjusting dampers 21 and 22 are operated, the operator switches the exhaust gas flow through a mechanical operation. At this time, the first and second opening degree adjusting dampers 21 and 22 There is a problem in that the operator has to go to the place where the heat recovery boiler 10 is installed in order to perform the mechanical operation, so that it is inconvenient for the operation work and can not cope quickly in a situation where rapid conversion is required as needed.

The present invention provides a built-in bypass function for automatic control of a door for bypassing exhaust gas, thereby solving the difficulty of securing a space for installation, and more particularly, And to provide a radio control door device for switching the exhaust gas bypass flow of a heat recovery boiler so that the convenience of shifting and the quick switching operation can be performed.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, there is provided a boiler comprising: a boiler body having a discharge pipe connected to the boiler body; A water tube assembly installed in the first and third spaces, respectively; A shutoff door means installed to open and close the first to third space portions separately between the boiler body and the hopper member; The blocking door means includes a first blocking door disposed in a state blocking the first space portion, a second blocking door disposed in a state blocking the second space portion, and a third blocking door disposed in a state blocking the third space portion First to third slide rails respectively protruding from the inner bottom surface of the boiler body facing the bottom surfaces of the first to third blocking doors, first to third slide rails provided on the bottom surface of the first to third blocking doors, And first to third slide grooves respectively formed to be slidable in a manner that the rails are inserted into the first to third sliding doors, There is provided a radio control door apparatus for switching the exhaust gas bypass flow of a heat recovery boiler provided with third driving means.

According to the present invention, the first to third drive means comprise a drive motor and a rack each having a pinion, and the drive motors of the first and third drive means are respectively fixed to both sides of the boiler body, The racks provided in the form of being drawn out from one side of the first to third blocking doors are connected to the radio control door device for switching the exhaust gas bypass flow of the heat recovery boiler engaged with the pinions of the first to third driving means drive motors Is provided.

In the present invention, the first to third signal receiving units are electrically connected to the driving motors of the first to third driving means, respectively, and the first to third signal receiving units are connected to the signal transmitting unit, And the signal transmitting unit is electrically connected to the operation panel, and a wireless control door apparatus for switching the exhaust gas bypass flow of the heat recovery boiler is provided.

If the radio control door apparatus for switching the exhaust gas bypass flow of the heat recovery boiler according to the present invention is used, the bypass tube bypassing the exhaust gas and provided outside the heat recovery boiler is removed, It is possible to solve the difficulty in securing the installation space, the difficulty in the installation of the opening control damper and the inconvenience in operation, and in particular, the door can be quickly and easily shifted for switching the flow of the exhaust gas, The effect that can be provided can be expected.

Figs. 1A and 1B show a general bypass external heat recovery boiler, wherein Fig. 1A is a cross-sectional view, and Fig. 1B is an internal view schematically showing Fig. 1A.
FIG. 2 is a view schematically showing an installed state of the water tube assembly as viewed in the direction of the hopper member of FIG. 1b.
3A to 3C show a wireless control door apparatus for switching an exhaust gas bypass flow of a heat recovery boiler according to the present invention, wherein FIG. 3A is a perspective view, FIG. 3B is a recessed view of the hopper member in FIG. Fig. 3C is a plan view showing the main part of Fig. 3A, and Fig. 3D is a main part perspective view showing a blocking door part.
4 is a view showing a case where the exhaust gas is not bypassed according to the radio control according to the present invention.
5 is a view showing a case where exhaust gas is bypassed according to the radio control according to the present invention.

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

As shown in FIGS. 3A to 3D according to the present invention, the heat recovery boiler 30 according to the present invention is constructed such that a discharge pipe 20 is connected to one side of a boiler body 11, And a steam drum 12 is installed on the upper surface of the boiler body 11 so as to collect the produced steam.

In the present invention, first and second partition walls 31 and 32 are arranged in parallel with each other in the interior of the boiler body 11, and by the first and second partition walls 31 and 32, And third spatial parts 33, 34, and 35, respectively.

A water tube assembly 37 communicating with the steam drum 12 is installed in each of the first and third space portions 33 and 35.

A hopper member 38 is fixedly installed on the other side surface of the boiler body 11 to which the discharge pipe 20 is connected so as to communicate with the internal space portion 36. The hopper member 38 Is connected to an exhaust gas supply pipe 39.

A shutoff door means 40 is provided between the boiler body 11 and the hopper member 38 for opening and closing the first and third space portions 33 and 35 individually.

The blocking door means 40 includes a first blocking door 41 slidably installed in a state of blocking the first space portion 33 and a second blocking door 41 slidably disposed in a state of closing the second space portion 34, The shutoff door 42 is slidably installed and the third blocking door 43 is slidably installed in a state closing the third space 35. [

In addition, the first to third blocking doors 41, 42, and 43 are provided on the inner bottom surface of the boiler body 11 corresponding to the bottom surfaces of the first to third blocking doors 41, 42, First, second, and third slide rails 44, 45, and 46 are provided in a protruding manner.

The first to third slide doors 44, 42 and 43 are slidably inserted into the bottom surfaces of the first to third slide doors 44, 1 to third slide grooves 47, 48, 49, respectively.

The first to third blocking doors 41, 42, and 43 installed as described above may be slidably disposed in a stacked manner by a thickness of the adjacent first to third blocking doors 41, 42, Are arranged in the direction of the thickness with the difference therebetween.

In order to control the movement of the first to third blocking doors 41, 42 and 43, the first to third blocking doors 41, 42 and 43 are connected to the first to third driving means 50, 51, 52). The first to third driving means 50, 51 and 52 comprise driving motors 56, 57 and 58 having corresponding pinions 53, 54 and 55, respectively, and racks 59, 60 and 61 .

More specifically, the drive motors 56 and 58 of the first and third drive means 50 and 52 are fixed to one side and the other side of the boiler body 11, respectively, The racks 59 and 61 provided in the form of being drawn out from the side surfaces of the first and third drive means 50 and 52 are respectively driven by the pinions 53 and 55 of the corresponding drive motors 56 and 58, Respectively.

The driving motor 57 of the second driving means 51 is fixed to one side of the boiler body 11 and the rack 60 provided in a form drawn out from the side surface of the second blocking door 42 And is engaged with the pinion 54 of the drive motor 57.

The first to third signal receiving units 62, 63, and 64 are electrically connected to the driving motors 56, 57, and 58 of the first to third driving units 50, 51 and 52, The first to third signal receiving units 62, 63 and 64 are communicatively connected to the signal transmitting unit 65 through a wireless channel and the signal transmitting unit 65 is electrically connected to the operation panel 66.

In the drawings, reference numerals S are formed in the first and second partition walls 31 and 32 so that the first to third blocking doors 41, 42 and 43 can be moved in the respective sliding positions.

[When exhaust gas is not bypassed]

The operator operates the operation panel 66 to transmit the corresponding drive signals to the drive motors 56 and 58 of the first and third drive means 50 and 52 from the signal transmission unit 65 The first and third signal receiving units 62 and 64 receive the transmission signal for the transmission signal.

When the first and third signal receiving units 62 and 64 receive the corresponding signals, the first and third driving units 50 and 60, which are electrically connected to the first and third signal receiving units 62 and 64, respectively, 52 to drive motors 56, 58, respectively.

The drive motors 56 and 58 of the first and third drive means 50 and 52 are driven in accordance with the applied electrical signal to cause the pinions 53 and 55 to rotate in the corresponding directions, The first and third blocking doors 41 and 43 interlock with each other and move in the direction of the second blocking door 42 with the movement of the racks 59 and 61 engaged with the first blocking doors 42 and 53 and 55.

As a result, the first and third blocking doors 41 and 43 are disposed so as to overlap with the second blocking door 42, whereby the first and third space portions 33 and 33, in which the water tube assembly 37 is installed, 35 are opened to communicate with the hopper member 38, and the second space portion 34 is closed.

The exhaust gas supplied to the exhaust gas supply pipe 39 passes through the first and third space portions 33 and 35 in the hopper member 38 and then flows out through the discharge pipe 20 do. At this time, the first and third space portions 33 and 35 are provided with water tube assemblies 37 through which water is circulated as described above, so that heat exchange between the exhaust gas and the water flowing to the water tube assemblies 37 And steam is produced.

[When exhaust gas is bypassed]

5, when an operator operates the operation panel 66 to transmit a corresponding drive signal to the drive motor 57 of the second drive means 51 from the signal transmission unit 65, The second signal receiving unit 63 receives the signal.

When the second signal receiving unit 65 receives the signal, the electric signal is applied to the driving motor 57 of the second driving unit 51, which is electrically connected to the second signal receiving unit 65.

The driving motor 57 of the second driving means 51 is driven in accordance with the applied electric signal so that the pinion 54 is rotated in the corresponding direction so that the rack 60 engaged with the pinion 54 The second blocking door 42 blocking the second space portion 34 is moved in the direction of the third blocking door 43 through the movement.

As a result, the first and third space portions 33 and 35 are kept closed, and only the second space portion 34 is opened to communicate with the hopper member 38.

The exhaust gas is bypassed from the hopper member 38 through the second space portion 34 and then discharged to the outside through the discharge pipe 20. As a result, the first and third space portions 33 The heat exchange between the water and the exhaust gas flowing to the water tube assembly 37 disposed in the heat exchangers 35 and 35 is not performed and the steam production is interrupted.

Therefore, when the wireless control door apparatus for switching the exhaust gas bypass flow of the heat recovery boiler according to the present invention is used, it is possible to solve the difficulty in securing the installation space by adopting a structure in which the bypass function is embedded, By automatically controlling the blocking door for bypassing by radio, the operation and inconvenience for switching the flow of the exhaust gas can be solved, and convenience and quick switching operation can be performed.

10, 30: Heat recovery boiler 11: Boiler body
12: steam drum 13, 36: inner space part
14, 37: Water tube assembly 15: Header
16: connector 17, 38: hopper member
18, 39: exhaust gas supply pipe 19: bypass tube
20: exhaust pipe 21: first degree-of-regulation damper
22: second degree adjustment damper 31: partition wall
32: second partition wall 33: first space part
34: second space part 35: third space part
40: blocking door means 41: first blocking door
42: second blocking door 43: third blocking door
44: first slide rail 45: second slide rail
46: third slide rail 47: first slide groove
48: second slide groove 49: third slide groove
50: first driving means 51: second driving means
52: third driving means 53, 54, 55: pinion
56, 57, 58: drive motor 59, 60, 61: rack
62: first reception signal section 63: second signal reception section
64: third signal receiving section 65: signal transmitting section
66: Operation panel

Claims (3)

First to third space portions 33, 34 and 35 partitioned through first and second partition walls 31 and 32 installed inside the boiler body 11 to which the discharge pipe 20 is connected;
A water tube assembly 37 installed in the first and third spaces 33, 34 and 35, respectively;
A shutoff door means 40 installed between the boiler body 11 and the hopper member 38 so as to open and close the first to third space portions 33, 34 and 35 individually;
The blocking door means 40 includes a first blocking door 41 disposed to block the first space portion 33 and a second blocking door 42 disposed to block the second space portion 34, , And a third blocking door (43) arranged to block the third space (35)
First to third slide rails 44, 45 and 46 protruding from the inner bottom surface of the boiler body 11 facing the bottom surfaces of the first to third blocking doors 41, 42 and 43, The first to third slide grooves 44, 45, 46 are respectively formed in the bottom surfaces of the first to third blocking doors 41, 42, 43 so that the first to third slide rails 44, 45, (47, 48, 49)
The first to third driving means 50, 51, 52 are installed on the first to third blocking doors 41, 42, 43 to control the movement of the first to third blocking doors 41, 42, Wherein the heat recovery boiler is provided with an exhaust gas bypass flow switching valve. The method according to claim 1,
The first to third driving means 50, 51 and 52 comprise driving motors 56, 57 and 58 each provided with a pinion 53, 54 and 55 and racks 59, 60 and 61, The drive motors 56 and 58 of the first and third drive means 50 and 52 are fixed to both sides of the boiler body 11 and the first to third shutoff doors 41, The racks 59, 60 and 61 provided in the form of being pulled out from one side of the drive motors 56, 57 and 58 of the first to third driving means 50, ) Of the heat recovery boiler (1).
3. The method of claim 2,
The first to third signal receiving units 62, 63 and 64 are respectively electrically connected to the drive motors 56, 57 and 58 of the first to third drive means 50, 51 and 52 The first to third signal receiving units 62 to 63 are communicatively connected to the signal transmitting unit 65 through a wireless channel and the signal transmitting unit 65 is electrically connected to the operation panel 66 Characterized in that the heat exchanger is a heat exchanger.

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