KR20120033074A - Combusion type caloriemeter and method of combusion type calorie measurement - Google Patents

Abstract

PURPOSE: A combustion type calorimeter and a combustion type calorimetric method are provided to enable accurate calculation by minimizing errors on energy efficiency calculation. CONSTITUTION: A combustion type calorimeter comprises a furnace(10), a main pipe(15), a branch pipe(30), a three way valve(33), a measuring unit(20), and a controller(40). A burner is included in the furnace. The main pipe injects the gas to the furnace. The branch pipe connects to both ends of an inlet and an outlet. The three way valve is formed in the inlet of the branch pipe. The measuring unit comprises a piezoelectric sensor. The controller measures the amount of moisture in gas by receiving the weight variation of the hygroscopic agent detected by the piezoelectric sensor.

Description

Combustion type caloriemeter and method of combusion type calorie measurement

The present invention relates to a combustion calorimeter and a combustion calorimetry method capable of measuring an accurate amount of heat regardless of the amount of water contained in the fuel.

Steel mills use LNG or LPG as fuel depending on by-product gases such as blast furnace gas from blast furnace, coke oven gas from coke distillation process and converter gas from smelting process in converter.

Most of these gas fuels are preheated to high temperature through a recuperator or heat exchanger using waste heat and then introduced into the combustor.

SUMMARY OF THE INVENTION An object of the present invention is to provide a combustion calorimeter and a combustion calorimetry method capable of accurately measuring calories regardless of the amount of water contained in a fuel.

Combustion calorimeter according to an aspect of the present invention is a combustion furnace including a burner; A main pipe through which gas is injected into the combustion furnace; Branch pipes connected at both ends of the inlet and outlet to the main pipe; A three-way valve formed at the inlet of the branch pipe; A measurement part including a hygroscopic agent partially filled on the branch pipe and a piezoelectric sensor positioned below the hygroscopic and detecting a weight change of the hygroscopic agent; and receiving a weight change of the hygroscopic agent detected from the piezoelectric sensor to receive a moisture content in the gas. It includes a control unit for measuring.

The measuring unit may further include a porous member positioned at both ends of the filled absorbent to fix the absorbent.

In particular, the porous member of the measurement unit may be coated with ABS resin.

The measurement unit may further include a door that can be opened and closed by a control unit on an upper portion of the moisture absorbent, and may further include a heater to dry the moisture absorbent when the door is opened.

Located on the inlet side of the branch pipe than the filler on the branch pipe, it may further include a cooling unit for cooling the gas flowing into the branch pipe.

The cooling unit may use cooling water, and the cooling water supply may be controlled by the control unit.

The thermocouple further includes a thermocouple on the branch pipe, and when the temperature detected by the thermocouple is higher than a reference temperature, the controller may supply the cooling water to the cooling unit.

The piezoelectric sensor may further include an OP-AMP that amplifies the signal when the signal is transmitted to the controller.

Combustion calorimetry method according to another aspect of the present invention comprises the steps of measuring the initial pressure from the piezoelectric sensor located at the bottom of the absorbent filled on the branch pipe connected to the main pipe of the combustion calorimeter; Changing the flow of gas flowing into the main pipe into the branch pipe; Passing a gas through the moisture absorbent for a reference time, measuring a calorific value during combustion of the gas in a combustion furnace, and changing a gas flow back into the main pipe; Measuring a pressure change relative to the initial pressure in the piezoelectric sensor and calculating a moisture content included in the gas based on the pressure change; And outputting the moisture content and the measured calorific value or correcting the calorific value in consideration of the moisture content.

Measuring a temperature of a gas flowing in the branch pipe; And cooling the gas when the measurement temperature is higher than a reference temperature.

When the gas is blocked by the branch pipe, the method may further include drying the absorbent by opening a door that opens and closes the upper portion of the absorbent.

In the combustion calorimeter of the present invention, the reference point of the energy efficiency calculation does not differ depending on the calorimeter, so that accurate control of the process is possible, and the error can be minimized in the energy efficiency calculation so that accurate calculation is possible.

1 is a conceptual diagram showing a combustion calorimeter according to an aspect of the present invention
FIG. 2 is a conceptual view illustrating a measuring unit of the combustion calorimeter of FIG. 1.
Figure 3 is a flow chart showing a combustion calorimetry method according to another aspect of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 is a conceptual diagram illustrating a combustion calorimeter according to an aspect of the present invention, and FIG. 2 is a conceptual diagram illustrating a measurement unit of the combustion calorimeter of FIG. 1. 1 and 2, the combustion furnace 10, the main pipe 15, the measurement unit 20, the piezoelectric sensor 21, the moisture absorbent 23, the porous member 25, the door 29, and the branch pipe 30. ), A thermocouple 31, a three-way valve 33, a cooling unit 35, a coolant valve 37, a control unit 40 and an OP-AMP 45 are shown.

 In steel mills, the calorific value of fuel is measured to control the supply of fuel or the combustion environment. There are two types of calorimeters used in steel mills, and a calorimeter using a gas chromatograph is used to automatically collect a combustion calorimeter or a sample gas.

Combustion calorimeter is more hampered in combustion as more moisture in the gas fuel is lower than the gas chromatographic calorimeter multiplying the ratio of the flammable components in the fuel gas by the low calorific value.

The present invention relates to a combustion calorimeter capable of measuring an accurate calorific value regardless of the amount of water contained in the fuel.

Combustion furnace 10 is a space for directly burning gas in order to measure calories in a combustion calorimeter, burns gas by applying heat from a burner, and main pipe 15 supplies a passage for supplying gas to the combustion furnace 10. to be.

As illustrated in FIG. 1, the branch pipe 30 bypasses the gas to measure the moisture content of the gas passing through the main pipe 15 by connecting both ends of the inlet and the outlet to the main pipe 15. The three-way valve 33 located at the inlet of the branch pipe 30 connected to the main pipe 15 opens and closes the valve to change the flow of gas flowing into the main pipe 15 into the branch pipe 30.

Measuring unit 20 is a device for measuring the amount of water contained in the gas is located on the branch pipe 30 and partially filled with the absorbent 23 and the absorbent 23 on the branch pipe 30, the absorbent (23) It includes a piezoelectric sensor 21 for detecting a weight change of the.

As the moisture absorbent 23, a substance having a property of absorbing moisture, such as silica gel or calcium chloride, may be used. When the amount of moisture absorbed by the moisture absorbent 23 increases, the moisture absorbent 23 presses the piezoelectric sensor 21 by gravity. As the force increases, the measurement value of the piezoelectric sensor 21 is changed, and thus the amount of moisture contained in the gas can be measured. Since the change in the amount of water is very minute, the size of the signal can be amplified by passing the OP-AMP 45 that amplifies the pressure sensing signal of the piezoelectric sensor 21. The OP-AMP 45 may use one having an amplifier performance of about 100 to 1000 times.

The measuring unit 20 may further include a porous member 25 at both ends to fix the absorbent 23 so that the filled absorbent 23 does not deviate from the piezoelectric sensor 21. The porous member 25 must be able to pass gas and water vapor while fixing the moisture absorbent 23, so that a hole is formed in the plate or a member having a mesh structure can be used.

At this time, since the porous member 25 is a high-temperature gas passes through, it is possible to prevent the porous member 25 from being deformed at a high temperature by using an ABS-based resin coated, such as SS400 epoxy coating.

The door 29 is positioned above the moisture absorbent 23, and when the gas does not flow to the branch pipe because the moisture content is not measured, the door 29 is opened to dry the moisture absorbent 23. If necessary, it may further include a heater (not shown) for applying heat to the moisture absorbent so as to evaporate quickly. If the moisture absorbent 23 is continued to be used without drying, the drying equipment is provided, such as a door or a heater, because the moisture absorbing ability of the moisture absorbent 23 may exceed the limit and the measurement may be inaccurate.

The cooling unit 35 is positioned near the inlet of the branch pipe to lower the temperature of the gas through heat exchange between the gas flowing through the branch pipe and the cooling water. In order to measure the precise moisture content of the gas moving to the measuring unit 20, the moisture is well collected in the absorbent when it is saturated, and thus serves to lower the temperature until the saturated or almost equivalent level.

The cooling water valve 37 serves to provide cooling water to the cooling unit 35, and may control the operation of the cooling unit 35 through opening and closing of the cooling water valve 37. The thermocouple 31 is a temperature measuring device located on the branch pipe. When the temperature sensed by the thermocouple is higher than the reference temperature, the thermocouple 31 may be controlled to operate. The reference temperature means a temperature at which the water of the gas is saturated or equivalent, and may be cooled by setting 70 ° C. as an example.

The control unit 40 is a device that controls the operation of the door 29, the thermocouple 31, the three-way valve 33 and the coolant valve 37 described above, and receives the measured values detected by each device and instructs an appropriate command. It measures the moisture of the gas in the combustion calorimeter.

3 is a flow chart showing a combustion calorimetry method according to another aspect of the present invention. Description will be made with reference to FIGS. 1 and 2, and descriptions overlapping descriptions of the combustion calorimeter will be omitted.

First, the initial pressure is measured from the piezoelectric sensor 21 located at the lower end of the absorbent 23 filled on the branch pipe connected to the main pipe 15 of the combustion calorimeter (S100).

Next, by changing the flow of the gas flowing into the main pipe 15 to the branch pipe (S200), after passing the gas through the absorbent 23 for a reference time, the calorific value of the combustion of the gas in the combustion furnace is measured, and the gas flow Change to the main pipe 15 again (S300), the piezoelectric sensor 21 measures the pressure change relative to the initial pressure, and based on this calculates the water content contained in the gas (S400). Reference time means a time appropriate for the absorbent to absorb moisture (for example, about 1 minute).

In order to measure the amount of pressure change to accurately measure the amount of water (S300), the gas temperature flowing through the branch pipe is measured to be higher than the reference temperature (S230) to operate the cooler to cool the gas to the reference temperature (S260). At this time, the amount of water does not necessarily need to be completely saturated, but by setting a temperature (for example, about 70 ° C.) that can be saturated over a predetermined level, the moisture can be absorbed by the absorbent 23.

The moisture content and the measured calorific value are output or the corrected value of the measured calorific value is output in consideration of the moisture content (S500). The door 29 is opened and a heater (not shown) is operated while the gas is not passing through the branch pipe to dry the moisture absorbent 23.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

10: combustion furnace 15: main pipe
20: measuring unit 21: piezoelectric sensor
23: absorbent 25: porous member
29: door 30: branch pipe
31: thermocouple 33: three-way valve
35: cooling unit 37: cooling water valve
40: control unit 45: OP-AMP

Claims (12)

A combustion furnace comprising a burner;
A main pipe through which gas is injected into the combustion furnace;
Branch pipes connected at both ends of the inlet and outlet to the main pipe;
A three-way valve formed at the inlet of the branch pipe;
A measurement unit including a piezoelectric sensor partially positioned on the branch pipe and a piezoelectric sensor positioned below the absorbent to sense a weight change of the absorbent;
Combustion calorimeter comprising a control unit for measuring the moisture content in the gas by receiving the weight change of the absorbent sensed from the piezoelectric sensor. The method of claim 1,
The measuring unit
Combustion calorimeter further comprises a porous member positioned at both ends of the filled absorbent to fix the absorbent. The method of claim 2,
The measuring unit
The porous member is a combustion calorimeter characterized in that the ABS-based resin is coated. The method of claim 1,
The measuring unit
Combustion calorimeter characterized in that it further comprises a door that can be opened and closed by a control unit on top of the moisture absorbent. The method of claim 4, wherein
Combustion calorimeter further comprises a heater for drying the moisture absorbent when opening the door. The method of claim 1,
Located on the inlet of the branch on the branch than the moisture absorbent,
Combustion calorimeter further comprises a cooling unit for cooling the gas flowing into the branch pipe. The method of claim 6,
The cooling unit is characterized in that using the cooling water,
Combustion calorimeter, characterized in that the cooling water supply is controlled by the control unit. The method of claim 7, wherein
Further comprising a thermocouple on the branch pipe,
When the temperature detected by the thermocouple is higher than the reference temperature
The control unit is a combustion calorimeter characterized in that for supplying the cooling water to the cooling unit. The method of claim 1,
And a OP-AMP for amplifying the signal when the signal of the piezoelectric sensor is transmitted to the controller. Measuring an initial pressure from a piezoelectric sensor located at a lower end of the absorbent filled on the branch pipe connected to the main pipe of the combustion calorimeter;
Changing the flow of gas flowing into the main pipe into the branch pipe;
Passing a gas through the moisture absorbent for a reference time, measuring a calorific value during combustion of the gas in a combustion furnace, and changing a gas flow back into the main pipe;
Measuring a pressure change relative to the initial pressure in the piezoelectric sensor and calculating a moisture content included in the gas based on the pressure change; And
And outputting the moisture content and the measured calorific value or outputting a corrected value of the calorific value in consideration of the moisture content. The method of claim 10,
Measuring a temperature of a gas flowing in the branch pipe; And
And burning the gas when the measurement temperature is higher than a reference temperature. The method of claim 10,
When gas is blocked by the branch pipe,
Combustion calorimetry method characterized in that it further comprises the step of drying the moisture absorbent by opening a door for opening and closing the upper portion of the moisture absorbent.

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