UA59869A - Device for holding cables under constant air overpressure - Google Patents

Abstract

Device for holding cables under constant air overpressure comprises connected in series between them a compressor, a heat-exchanger, a humidity separator, an adsorber and a back-pressure valve connected to adsorber outlet. To outlet of the valve there are connected main receiver, pressure gauge in this receiver with control device and step-down reducer with readout gate connected to it outlet. To outlet of the adsorber there is also connected a throttle to outlet of which additional receiver is connected. Electropneumatic valve is connected to humidity separator, and also second electropneumatic valve. The device is equipped with additional back-pressure valve which inlet is connected to the outlet of step-down reducer, and outlet is connected to common point of the throttle and additional receiver.

Description

Description of the invention

The invention relates to devices for drying and stabilizing air pressure, which are used. in 2 devices that consume dry air with excess and stabilized pressure, for example, when operating communication cables, in which dried air with excess stabilized pressure is used to protect against moisture and control the tightness of the sheaths.

The closest in terms of technical essence to the claimed device is a device for holding cables under constant air overpressure, containing a series-connected compressor, a 710 heat exchanger, a moisture separator, an adsorber, a non-return valve connected to the adsorber outlet, connected to the outlet of the non-return valve, the main receiver, a pressure gauge in this receiver with a control device and a reducing reducer with an outlet valve connected to it, as well as a throttle connected to the outlet of the adsorber, to the outlet of which an auxiliary receiver is connected, and a drain electro-pneumatic valve connected to the moisture separator, as well as a second an electropneumatic valve, the input of which is connected to the 19th output of the main receiver, and the output to the output of the auxiliary receiver (see the Conclusion of the Ukrainian Institute of Industrial Property on Issuing a Declaratory Patent for an Invention Based on the Results of an Expertise on Local Novelty in Application Mo2002031827 of September 11, 2002, IPC " VO1053/04, HO2O1 /00).

In the device according to the prototype, air drying is performed with the help of one adsorber in two stages. At the first stage, the air pumped by the compressor is cooled, droplets of moisture are separated from it, and 720 it enters the adsorber, where it is finally dried, passes through the non-return valve and accumulates in the receiver, and from there, through the reducing gear and the outlet valve, it reaches the consumer (cables connection). At the second stage, the adsorbent is regenerated by passing a part of the dried air through the adsorber in the reverse direction. At the same time, the air takes over the moisture of the sorbent and is released into the atmosphere through the moisture separator and the drain electropneumatic valve. 29 The moments of switching on and off the compressor and drain electropneumatic valve are determined by the control device based on the results of the pressure measurement in the receiver using a pressure gauge.

When the pressure in the main receiver reaches the upper setpoint, the compressor shuts off and the electropneumatic drain valve opens. The flow of dry air from the auxiliary receiver through the throttle enters the adsorber, absorbs moisture from the sorbent and is released into the atmosphere through the moisture separator and the drain Ф 3о electropneumatic valve. (Se)

When the pressure in the main receiver (due to the flow of dry air to the consumer) drops to the lower set pressure value, the compressor is turned on, the drain electro-pneumatic valve is closed, and the process of air drying and its accumulation in the main and auxiliary receivers begins again. When the pressure in the main receiver again reaches the upper set value, the compressor is turned off, the drain electropneumatic valve opens and the cycle of the device is repeated. and

The difference of the known device is that the regeneration of the sorbent is carried out with the help of air that accumulates in the auxiliary receiver, and with the help of an electropneumatic valve installed between the auxiliary and the main receiver, additional back-purging of the adsorber is provided and, thus, "and regeneration of the sorbent in those cases , when the output flow of dry air to the consumer is too large, for example, in case of an accident (depressurization) of a communication cable. c A characteristic feature of the operation of communication cable retention systems under increased air pressure is: c» that the maximum flow of dry air occurs only when the cable sheath is damaged. In other cases, the flow of dry air to the consumer (cable) is minimal and may even be absent. In this case, the moisture that is always present in the sorbent is distributed over the entire volume of the adsorber, including in the completely dried protective layer.

If the cable sheath is damaged, the air flow rate at the output of the device increases sharply, the pressure in the main receiver (Se) decreases to the lower set value, the compressor is turned on and the flow of moist air is directed into the receiver and further into the protected cables.

The disadvantage of the known device is that the control of the operation of the compressor and drain electro-pneumatic

Ge) 50 valves are operated by the control device according to the signal of the pressure gauge in the main receiver and at a time when the air flow rate at the outlet of the device is small or completely absent, the air from the auxiliary receiver will completely exit and the adsorber becomes unprotected, because the moisture that is in the layers sorbent, which are at its entrance, spread throughout the adsorber volume, and in case of damage to the cable, the air flow will increase and moist air will enter the cable.

The invention is based on the task of improving the device for holding cables under the constant air excess pressure, in which due to the introduction of an additional non-return valve installed in a certain way into the device, constant purge of the adsorber is ensured even in those cases when the output flow of dry air in the cable is too small or absent at all and, as a result, the possibility is excluded ingress of moist air at the output of the device in all cases, both with the tightness of the consumer bo (cable), and with its violation, which will lead to an increase in the reliability of the operation of communication cables.

The specified task is solved thanks to the fact that the device for holding cables under constant air overpressure, which contains a series-connected compressor, heat exchanger, moisture separator, adsorber, a non-return valve connected to the adsorber outlet, a main receiver connected to the non-return valve outlet, a meter of pressure in this receiver with a control device and a reducing bo reducer with an outlet valve connected to it, as well as a throttle connected to the outlet of the adsorber, to the outlet of which an auxiliary receiver is connected, and a drain electro-pneumatic valve connected to the moisture separator, in addition, the device contains a second electro-pneumatic valve, the input of which is connected to the output of the main receiver, and the output to the output of the auxiliary receiver, according to the invention, it is equipped with an additional non-return valve, the input of which is connected to the output of the reducer, and the output is connected to the common point of the throttle and the auxiliary receiver, it is optimal when the device is equipped with an additional th throttle, which is installed in series with an additional non-return valve.

The cause-and-effect relationship between the claimed set of features and the technical results achieved during its implementation is as follows. 70 Due to equipping the device for holding cables under constant air overpressure with an additional non-return valve, the input of which is connected to the output of the reducer, and the output to the common point of the throttle and the auxiliary receiver, it becomes possible to regenerate the adsorber not only under normal operating conditions of the device, but also in the case when the consumption of dry air to the consumer is minimal or absent, that is, regeneration of the adsorber during a pause in the compressor is performed constantly. Therefore, in the case of /5 Damage to the cable sheath, despite the fact that the air flow increases sharply, moist air will not be able to get to the consumer (into the cable), because a dry protective layer of sorbent always remains in the regenerating adsorber, thanks to constant back-purge.

In the proposed device, dry air is produced in any case: both when the consumer (cable) is sealed, and when it is broken, which will ultimately lead to an increase in the reliability of the operation of cables and communication systems in general.

Thanks to the additional throttle introduced into the device, which is installed in series with the additional non-return valve introduced by us, the level of consumption of dry air, which comes from the main receiver for regeneration of the sorbent, is adjusted.

The device for holding cables under constant air overpressure is illustrated by drawing ov (SEE Fig.).

The device for holding cables under constant air overpressure contains a compressor 1, a heat exchanger 2, a moisture separator 3, an adsorber 4, connected to the outlet of the adsorber 4, a non-return valve 5, connected to the outlet of the non-return valve 5, the main receiver 6, a gauge of pressure 7 in this receiver 6 with the control device 8 and the reducing reducer 9 with the output Ge! with a valve 10, as well as a throttle 11 connected to the outlet of the adsorber 4, to the outlet of which an auxiliary receiver 12 is connected, and a drain electro-pneumatic valve 13 connected to the moisture separator C, and an electro-pneumatic valve 14 is installed between the main receiver 6 and the auxiliary receiver 12, while the device is equipped with an additional non-return valve 15, the input of which is connected to the output of the reducer 9, and the output is connected to the common point of the throttle 11 and the auxiliary receiver 12, and if necessary, the device is equipped (22) with an additional throttle 16, which is installed in series with the additional check valve 15. y

A device for holding cables under constant air overpressure works as follows. Compressed air from compressor 1 goes to heat exchanger 2, and then to moisture separator 3. Compressor 1 takes ordinary air from the surrounding environment. In the heat exchanger 2, air is cooled, and in the moisture separator Z, the air is pre-dried due to the partial condensation of the moisture that falls out during the cooling of the compressed air in the heat exchanger 2. After the moisture separator Z, the pre-dried air from c enters the adsorber 4, where it is finally dried, passes through the return valve 5 and

І accumulates in the main receiver 6, goes to the reducing reducer 9, where it decreases and stabilizes і? its pressure is, for example, at the level of 5OkPa, and through the outlet valve 10 it reaches the consumer (cables). At the same time, part of the dry air from the adsorber 4 through the throttle 11 enters the auxiliary receiver 12, but the main part of the dry air enters the auxiliary receiver 12 from the main receiver b through the electropneumatic valve 14, which is open while the compressor 1 is working and the process of drying the air is underway. When the pressure in the main receiver 6 reaches the upper set value, determined with the help of and, the pressure gauge 7 and the control device 8, at the command of this control device 8, the compressor 1 is turned off, as well as the drain electropneumatic valve 13, connecting the moisture separator C with the atmosphere , 50! electropneumatic valve 14, disconnecting the main receiver b and the auxiliary receiver 12. Sorbent,

Me, for example, silica gel, in the adsorber 4 due to the dry air that has accumulated in the auxiliary receiver 12 and

He enters through the throttle 11 to this adsorber 4, begins to dry. Next, the air that has absorbed moisture from the sorbent (silica gel) is released into the atmosphere through the drain electro-pneumatic valve 13. At this time, due to the costs at the output of the device, the pressure in the main receiver 6 begins to decrease. The sorbent regeneration process in the adsorber 4 will continue until the pressure in the receiver 6 reaches the lower set level. At the same time, at the command of the control device 8, according to the signal of the pressure gauge 7, the compressor 1 will turn on again, drain

P" electropneumatic valve 13 will block the connection of moisture separator C with the atmosphere, and electropneumatic valve 14 connects the main receiver b with the auxiliary receiver 12. Air begins to accumulate again in the main receiver 6 and the auxiliary receiver 12 and the cycle of the device ends. 60 During a pause in the operation of compressor 1, back-purging of adsorber 4 with dry air is carried out with the help of dry air from the auxiliary receiver 12 through the throttle 11. When the supply of dry air in the auxiliary receiver 12 is exhausted and the pressure in the auxiliary receiver 12 is equal to the air pressure after the reducing reducer 9, the adsorber 4 is purged with dry air from the main receiver 6 through the reducer 9 and the second non-return valve 15 introduced by us. 65 This circumstance, during a pause in the operation of the compressor, prevents the redistribution of moisture present in the adsorber 4 throughout the entire volume of the adsorber 4 , when the consumption of dry air is minimal or completely absent. When the consumption of dry air, for example, when the cable sheath is damaged, increases sharply, when the device is switched to the drying and pumping mode, there is a danger of moist air getting into the main receiver 6 and further to the consumer (into the cable). Additional purging of the adsorber 4 with dry air from the main receiver 6 during a pause in the operation of the compressor 1 (adsorber 4 is regenerated) through the additional check valve 15 prevents this phenomenon.

Regulation of the level of consumption of dry air, which comes from the main receiver 6 for the regeneration of the sorbent in the adsorber 4, is performed with the help of the throttle 16 introduced by us.

Claims (2)

The formula of the invention 1. A device for holding cables under constant air overpressure, containing a series-connected compressor, heat exchanger, moisture separator, adsorber, a non-return valve connected to the adsorber outlet, to the outlet of which the main receiver is connected, a pressure gauge in this receiver with a controller device and a reducing reducer with an outlet valve connected to it, as well as a throttle connected to the adsorber outlet, to the outlet of which an auxiliary receiver is connected, and a drain electro-pneumatic valve connected to the moisture separator, as well as a second electro-pneumatic valve, the input of which is connected to the output of the main receiver, and output - to the output of the auxiliary receiver, which differs in that 20. THAT it is equipped with an additional non-return valve, the input of which is connected to the output of the reducer, and the output is connected to the common point of the throttle and the auxiliary receiver. 2. The device according to claim 1, which is characterized by the fact that an additional throttle is included in series with the additional non-return valve. « (o) Zo Te) (ee) (o) And c) - and? 1 se) (ee) (o) iChe) 60 b5