SU894520A1 - Device for compressed gas humidity checking - Google Patents

Description

(H) DEVICE FOR CONTROL OF HUMIDITY OF COMPRESSED The invention relates to a test and measurement technique, and more specifically to devices for controlling the humidity of compressed gas, and is intended for use in various installations and devices of systems using high-pressure gases. A device is known for measuring the moisture content of a gas on the principle of varying the capacitance of a capacitor using dielectrics absorbing moisture. A device is known for measuring the moisture of a gas, which uses the principle of misting the cooled mirror at a growing point while cooling the spin box is produced by the flow of the gas under study. fixing the moment of mirror fogging is used visual control 2. However, these devices have a complex structure, special gain blocks, frequency generators, etc.

GAS require their work electric power sources. Havt & Miee closest to the present invention is a device for controlling the humidity of a compressed gas, containing an analyte gas pipeline to which a dew point indicator is connected with a condensation surface temperature controller, a dew point indicator cooler made in the form of an expansion point installed behind the dew point indicator with an expansion chamber Ez. The drawbacks of this device are the design complexity, low efficiency due to the need to use an ineffective thermoelectric effect, or insufficient use of the energy of the test gas for cooling, as well as insufficient accuracy and reliability, since the measurement of the moisture of the compressed gas requires visual monitoring, or is not carried out. 8, the compressed gas stream under study, and after its throttling. The purpose of the invention is to improve the accuracy, reliability and efficiency of controlling the humidity of compressed gases, as well as simplifying its design. This goal is achieved by the fact that in a device for controlling the humidity of a compressed gas, containing an analyte gas pipeline, to which a dew point indicator is connected with a condensation surface temperature controller, a dew point indicator cooler, made in the form of a drop point installed behind the dew point indicator, The dew point indicator is located in the pipeline in the area that is placed in the expansion chamber, and the condensation surface temperature controller is designed as a flow controller throttling sections with an indicator of the position of this regulator. In addition, a pipeline section with a dew point indicator can be used as a regulator of the throttle bore. Drossel walls are formed by a pipeline section with a dew point indicator. In FIG. 1 shows a device for controlling the humidity of compressed gas} in FIG. 2-6, embodiments thereof. The device has a pipeline 1. the analyzed gas, the indicator 2 of the dew point, made 8 as a mesh of heat-conducting liquid condenser, part of the pipeline 1 with the indicator 2 dew point covers the expansion chamber 3 having an inlet k and an outlet 5 for the cooling medium. After the dew point indicator 2, in the direction of gas movement, a throttle 7 is connected via a pipe 6, On the other hand, a throttle 7 is connected to the inlet of the expansion chamber 3. Before the indicator 2 drops of dew and after it the pressure switch 8 is turned on. The expander on chamber 3 is outside covered with heat radiation. Throttle 7 has a 10-temperature regulator of the condensation surface, made in the form of a regulator of its flow area and an indicator 11 of the position of this regulator. The pipe wire 1 of the device is connected to line 12 of compressed gas through a stop valve 13. 0. 4 In FIG. 2 and 3, the pipeline section with the dew point indicator has a well-developed heat-conducting surface and drills T for gas passage made therein, and the throttle 7 is installed along the gas flow behind the dew point indicator directly in the expansion chamber 3H in FIG. 5 and the walls of the throttles 7 are formed by a section of the pipeline 1 of the gas to be analyzed with a 2 dew point indicator, and this section of the pipeline has a developed heat-conducting surface made in the form of heat-conducting fins 15 "forming the channels of the gas passage. FIG. 6 shows an embodiment of a device for controlling the humidity of a compressed gas, in which the dew point indicator 2 is made movable with respect to a portion of pipeline 1 of a controlled gas and, together with this portion of the pipework, is simultaneously a throttle 7 and a condenser surface temperature regulator 10 (throttle cross section regulator / The device operates as follows: The monitored compressed gas from line 12 through valve 13 is directed to pipeline 1, where it passes through the dew point indicator 2 (mesh heat conduction liquid condenser), after which it enters the pipe 6 and is directed to the throttle 7. When throttled in the throttle 7, the gas reduces the pressure and is cooled by the throttle effect. After the throttle, the cooled gas is directed to the inlet C of the expansion chamber 3, it is even more cooled by expansion and cools the pipeline 1 along with the dew point indicator 2 it contains. By cooling the dew point indicator 2 the compressed controlled gas cools and the moisture in it drops out a liquid in the mesh condenser 2 at a temperature of the dew point. This causes the hydraulic resistance of the dew point indicator 2 to increase and the pressure differential sensor 8 is triggered, signaling an unacceptable moisture concentration in the controlled compressed gas. If it is necessary to change the dew point temperature and at different pressures of the controlled gas, as well as

gas composition of different composition, the throttle 7 is controlled by the adjusting device 10, and the position indicator 11 indicates the values of the dew point temperature (humidity) on a predetermined scale.

In contrast to the device for controlling the humidity of compressed gas and the version of this device shown in FIG. 1-3, the S embodiment shown in FIG. 4 and 5, the cooling of the dew point indicator 2 partially occurs directly through the walls of the throttles 7 due to the throttle effect when gas is throttled in the throttle 7.

In contrast to the device for controlling the humidity of compressed gas and its variants shown in FIG. 1-5, in its embodiment shown in FIG. 6, throttling and partial cooling of the controlled gas occurs directly in the grid indicator, while the controlled compressed gas undergoes sequential processes of throttling, flow from one grid cell to another with small pressure drops, while passing through the indicator results in an integral cooling effect, and This effect is controlled by changing the working length of the indicator involved in throttling. Further cooling of the compressed gas also occurs in the devices shown in FIG. 1-5 Using part of the controlled gas to cool it to the required dew point of the net condenser located in the pipeline section with controlled compressed gas improves the efficiency of the device, reliability of operation and measurement accuracy, as well as simplifies its design.

Claims (3)

1. A device for controlling the humidity of the compressed gas containing the pipeline of the analyzed gas to which the dew point indicator is connected with the condensation surface temperature controller, the cooler of the dew point indicator, made in the form of a droplet mounted behind the dew point indicator with an expansion chamber, In order to simplify the design, increase the efficiency, accuracy and reliability of controlling the humidity of the compressed gas, the dew point indicator is located in the pipeline at the site that is placed in Sitreni, and reg. The torus of the condensation surface temperature is made in the form of a throttle bore adjuster with a position indicator of this regulator. 2. The device according to claim 1, about tl and her tea with the fact that as a the throttle bore adjuster used a pipeline section with a dew point indicator. 3. The device according to claim 1, which is based on the fact that the walls of the throttles are formed by a section of the pipeline with an indicator of the dew point. Sources of information taken into account in the examination t. Patent of France No. 2327536, cl. G Ot N 27/22, 1977. 2. US Patent And, cl. 73-17, 1972. 3. The patent of France No. 2087827, class, G OT 25/00, 1971 (prototype). -BUT igz