SU17806A1 - Method of measuring calorific value of gaseous fuel - Google Patents

Description

The invention relates to methods and devices for measuring the calorific value of a gaseous fuel continuously supplied to the burner, as determined by a continuous stream of heat absorbing liquid.

In commonly used devices for determining calorific value, the combustion air was supplied to the gas being burned, having a moisture level (relative to the saturated steam) that it had by chance in the room where the experiment was performed. The test gas was usually completely saturated with moisture, as it was passed through a gas meter fitted with a liquid lock. Similarly, the exhaust gases coming out of the calorimeter, usually cooled to a temperature equal to the initial temperature of the water that cools the calorimeter,

they usually turned out to be completely full of sourced v. tag. Following this, for accurate measurements of power production, it was designed as a single | P () oxspeAe

Deviations of temperature and degree of humidity for air, test gas and exhaust gases, and then, by means of very complex calculations, make an amendment to the measured value of heat output. Meanwhile, such corrections can be made only when single (one-time) measurements of the calorific value are made; These amendments are not applicable in cases where the measurement of heat output should be carried out continuously using an automatic recording device.

The proposed method and device allow automatic measurement of heat output not affected by the temperature and degree of humidity of the air that is in the room at the moment in which the device is installed, which is achieved by the combustion air that is supplied to to the calorimeter of the occluding 8d at at the same time it worked out the combustion products, it is brought to the same temperature and, moreover, because of the gases that fit the calorimeter (test gas and combustion air), as well as gases flowing from non-O1 (exhaust gases) are equally saturated with humidity, best of all, until complete saturation. Thanks to the same temperature and the same degree of humidity as the calves entering the calorimeter, -What is at a certain temperature. All the time, the same percentage of moisture (referred to the total total amount of gases) is supplied to the calorshlet and that the same percentage of moisture is removed by the I8 calorimeter together with the spent gases, as a result of which the amount of water deposited in the calorimeter is exactly equal to The burning process. The amount of water, and the degree of heating of the coolant, the calorimeter of water corresponds to the true calorific value.

In order that the temperature of the exhaust gases can always be equal to the temperature of the cooling water entering the calorimeter, the quality of the initial temperature — this temperature of the incoming water — that is, i.e. gas and combustion air are brought in just before they are released into the calorimeter to the same temperature and, at the same time, saturate these gases with moisture. In order to obtain an exact coincidence of temperatures, moreover, they arrange a exchange between the cooling water and the combustion air supplied to the calorimeter. garbage fuel. At the same time, the cooling water calorimeter is forced to circulate in a closed flow and the heating calorimeter in the calorimeter is cooled again in a special secondary refrigerator to maintain the lower temperature limit. This lower limit for circulating water can, for example, be very easily maintained at a strictly constant level with the help of a thermostat regulating (Amount of coolant supplied.

In the lower limit temperature kaestpe, the air temperature in the room in which the ca-orshire is located is trapped, then the temperature of the cooling water flowing to the calorimeter is adjusted to this temperature range. This is advantageous because the combustion air, as well as the measurable gas, already has this temperature, and all that remains is to take measures to saturate the air supplied to the combustion with moisture.

The drawing shows schematically the devices used to implement the method of measuring the calorific value, with FIG. 1 and 3 show devices, n) assigned to an automatic calorimeter, FIG. 2 is a modification of the device shown in FIG. 1, intended for a calorimeter making single (one-off) measurements.

Corresponding parts are marked on different figures with the same figures.

The test gas is burned in the burner 2, and the exhaust gases give up their heat to the water flowing through the calorimeter 1 and are released into the atmosphere through the nozzle 3. Cooling water (arrows W) flows from tank 4 first to the water meter 5 forcibly connected to the gas meter 6 that the ratio of the amount of water to the amount of the test gas is always the same; Then, water passes through pipe 7 to calorimetric vessel 1, leaves the latter through an overflow pipe 8 and enters a secondary cooler 9, in which it is cooled to a certain lower temperature limit by means of a special cooling fluid flowing through pipe 10 to vg 1 flowing through pipe 11. The lower puncture of the temperature can be maintained at a constant level with the help of a temperature regulator, in which the temperature sensitive part 12 is inserted in the path of the flowing water, which serves to cool the calorimeter, and The rag 13, which performs the adjustment, is inserted into the pipe 10, through which the secondary cooling fluid flows into the refrigerator. From the cooler 9, the cooling calorimeter water flows along the pipe 16 into the reservoir 16 located in the vise, from which water is pumped by the pump 17 through the pipe 18 to the gas meter b, from which it passes through the pipe 19 back to the tank 4. Kaso 17