DE202917C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- ΛΙ 202917 CLASS 42 /. GROUP

RUDOLF MICHEL in BRUCKHAUSEN a. Rh.

Method for determining the calorific value of flammable gases.

Patented in the German Empire on June 26, 1907.

The object of the invention relates to a method for continuous, automatic Determination and recording of the calorific value of a flammable gas or steam. As is well known the calorific value of a constantly cooled gas results from the equation

W. H (tt)

ίο where G is the amount of fuel that burns in a certain time, W is the amount of cooling flowing through in the same time and t " or t _{0 is} the coolant inflow or outflow temperature. In order to determine the calorific value directly in a simple manner without having to calculate each time, according to the present invention the product W (t ₀ -: t _n ) is kept constant, so that the calorific value is obtained from the amount of fuel G displayed on a gas meter.

For this purpose, a certain amount of heat is generated by burning a gas, recorded in a gas calorimeter and the amount of gas that is necessary to generate this amount of heat is measured. In order to generate a certain amount of heat in the gas calorimeter α , both the water or liquid inflow and the temperature of the inflowing and outflowing water must be kept constant. The amount of inflowing water is kept constant by a constant pressure head and the same inlet opening and the temperature of the inflowing and outflowing water in a manner known per se by thermoregulators.

The drawing shows the schematic representation of the apparatus.

The amount of inflowing water, which enters at b , is kept constant by a constant pressure head and an equal inlet opening, which can be regulated by a tap with a pointer, as is already attached, for example, to the Unker patent calorimeter. To keep the temperature of the water flowing off at c constant, a thermoregulator is used, which works by the expansion or contraction of an enclosed liquid or gas of the gas flow, which enters the thermoregulator e at d and from there through the pipe / to Burner is directed, regulated, so that when the temperature is increased, the gas flow is reduced, while the gas flow is increased when the temperature is lowered. The temperature of the water flowing through the tube g to the calorimeter. is kept constant in that a corresponding amount of the outflowing warm water flows through a thermoregulator h to the cold inflowing water and is thereby brought to a certain temperature.

The thermoregulator h consists of a container, in the lower part h ^{1 of} which there is a liquid i with a large expansion coefficient, such as benzene, ether, chloroform, etc., or a gas, vapor or a mixture of a gas with the vapor of a high-tension liquid, such as B. ether, chloroform, carbon tetrachloride, etc., are located

det, which is sealed against the tube mouth V- , which extends from the upper part into the lower part, by mercury k or other heavy liquid which does not enter into contact with the gas or the water. A tube provided with various openings, which is connected to the water drainage pipe c, also protrudes into the shut-off liquid. The temperature fluctuations

ίο corresponding to the water that emerges from the tube I into the upper container part A ³ and is fed from here through the tube m to the inflowing cold water, the volume of the enclosed gas or liquid i experiences a corresponding increase or decrease, causing a rise or a falling of the shut-off liquid k , in which tube A ^{2 is} conditioned and thereby the openings of the tube / are more or less covered, so that depending on the temperature of the water there is a greater or lesser outflow of the same.

Since the amount of water flowing through is constant at the same times and the inlet and outlet temperatures are kept constant, the calorimeter absorbs the same amounts of heat at the same times, and the amount of the gas supplying this amount of heat is measured by observing the gas meter. The amount of heat given off during the combustion of the gas is therefore inversely proportional to the gases consumed in a certain period of time. The calorific value is determined after setting the amount of water flowing through and the temperatures by reading the gas meter, in that the amount of gas consumed in a certain time is assigned corresponding calorific values. For example, the passage of the water is 40 1 per hour, the inlet temperature is io ° C. and the outlet temperature 25 ⁰ C, and therefore the amount of heat absorbed per hour:

(25-10) x 40 = 600 W. E. Is the one on the gas meter read amount of gas consumed =. 120 1 per hour, so the calorific value is per ι cbm of gas

600
120

■ 1000 = 5000 WE,

at 130 1 hourly gas consumption, the calorific value would then be per 1 cbm

₌ - ⁰⁰ L. _IOO o = 4616 WE

130

Claims (2)

Patent-to sayings: 1. Procedure for determining the calorific value of flammable gases, their combustion products give off their heat in a constant stream to a coolant also constantly flowing through a cooling device, thereby characterized in that the amount, initial temperature and final temperature of the Coolant can be kept constant, and, accordingly, the temperature of the inflowing Combustion products changed by changing the amount of gas that is burned will. 2. Apparatus for carrying out the method according to claim 1, characterized by such a connection of the cooling device (a) with two thermostatic devices (h ³ , I and e, d) and an overflow (b) for the incoming coolant that part of the outflowing coolant in a degree controlled by the first thermostat (h ³ , I) to the coolant flowing in through the overflow (b) at m) this is heated, and that by the second thermostat (e, d) to an extent that by the coolant leaving the cooling device is regulated, the flow of combustion gas to the burner is changed. 1 sheet of drawings.