SE539845C2 - Pressure reducing valve for device for degassing liquid mixtures - Google Patents

Abstract

. Vacuum setting valve for device for degassing certain substances in liquid mixtures was at boiling point in closed liquid systems, where a subset of the liquid is separated for degassing and where degassed liquid is returned to the closed system, where the vacuum setting valve is arranged to be on a line in which said portion . The invention is characterized in that the vacuum setting valve, the vacuum valve, comprises a housing (31; 32) with an inlet (11; 21) and an outlet (16; 26) for the separated liquid, the vacuum valve comprising a piston (12; 22) movable in the housing arranged to restrict to a greater or lesser extent the supply of the liquid separated to the vacuum valve, by a pump being connected downstream of the vacuum valve, by a compression spring (14; 24) being arranged between one end wall (17; 27) of the piston (12; 22) and the housing, in that a channel (13; 23) is provided through the piston, which channel connects the inlet (11; 21) / outlet (16; 26) of the vacuum valve to the side of the piston (12; 22) facing said spring (14; 24) and because the piston is sealed to the inside of the housing (31; 32).

Description

The present invention relates to a valve for device for degassing liquid mixtures. With an increasing amount of energy wells, such as rock heat, and energy storage, as well as indirect cooling technology systems such as cold storage, ice rinks, etc., substances with a low boiling point are added to prevent freezing in the pipelines. Examples of such additives are ammonium hydroxide where ammonia in 12.5% ammonium hydroxide has a boiling point of 39 degrees C and ethyl alcohol having a boiling point of 78.5 degrees C, both at atmospheric pressure.

It is common for plastic pipes to be used to transport the liquid in the systems. Plastic pipes are non-diffusion-tight, without gases such as oxygen, nitrogen and carbon dioxide, and also other gases, can diffuse in from the environment to the liquid in the systems. Even when using metal pipes, leakage takes place via joints in the system. gas leakage can also occur from a gas-filled equipment connected to a fluid system. Such equipment may be cooling machines.

A major problem with heating and cooling systems containing a heat-carrying liquid is corrosion inside the systems. Furthermore, substances that mainly oxygen, nitrogen, carbon dioxide cause the attenuation energy efficiency to decrease as these substances can settle on heat exchangers, which act as insulators and settle in pumps that reduce the efficiency of the pumps. In addition to oxygen, nitrogen and carbon dioxide, there may be other substances that are desired to be removed, such as hydrogen sulfide or sulfur dioxide or refrigerant gas.

There are different types of corrosion in such systems, such as general corrosion, galvanic corrosion, erosion corrosion, crevice corrosion, microbiologically induced corrosion and local pit corrosion.

Water quality is of great importance for the corrosion process. In the first place, corrosion depends on, among other things, the amount of solutes, gases dissolved in the liquid, pH value, temperature, etc. A condition that is very decisive is the concentration of dissolved oxygen in the liquid, since oxygen is necessary for an oxidation process.

In closed water systems, which is prevalent today, the gases, including air, released from the liquid will appear as bubbles at high points in the system.

The ability of water to dissolve air depends on temperature, pressure and salinity. Water dissolves more gas at higher pressures and lower temperatures.

The oxygen consumed during oxidation inside the system is replaced by oxygen from the environment leaking into the system in order to achieve equilibrium with regard to oxygen in the system.

Therefore, systems need to be degassed to lower the oxygen content of the system.

Furthermore, nitrogen and carbon dioxide need to be removed from the systems due to their negative impact on heat exchangers and pumps.

To remove harmful gases, such as oxygen, nitrogen and carbon dioxide, the liquid mixture can be subjected to a negative pressure, whereby the gases escape. Such a lowering of the boiling point unfortunately means that the additives for a freezing point reduction are expelled from the liquid mixture before the said harmful substances.

Swedish patent no. 1551369-0 describes an invention which solves this problem.

A problem with a system according to said patent is that the setting of the pressure reducing valve must be changed manually when there is a change of the pressure in the closed system.

The reason for a change in pressure can be a change in the temperature of the liquid flowing in the closed system, leakage of liquid from the system or that an intervention has been made in the system.

Therefore, in order for the desired negative pressure in the separated part where degassing is to take place to be maintained at the desired level in order to thereby ensure that desired compounds and substances are separated, the pressure reducing valve must therefore be set after a pressure change has taken place in the closed system.

The present invention solves this problem.

The present invention relates to a pressure reducing valve for a device for flue gas certain substances in low boiling point liquid mixtures in closed liquid systems, where a portion of the liquid is separated for degassing and where degassed liquid is returned to the closed system, where the pressure reducing valve is arranged in a line is intended to flow, and is characterized in that the pressure reducing valve comprises a housing with an inlet and an outlet for the separated liquid, the pressure reducing valve comprises a piston movable in the housing arranged to restrict to a greater or lesser extent the supply of the liquid separated to the pressure reducing valve pump connected downstream of the pressure reducing valve, in that a pressure spring is arranged to act between one end wall of the piston and the housing, in that a channel is present through the piston, which channel connects the inlet / outlet of the pressure reducing valve to the side of the piston facing said spring and t the piston is sealed against the inside of the housing.

The invention is described in more detail below, partly in connection with exemplary embodiments shown in the accompanying drawings, in which - Figure 1 illustrates a method for degassing compounds and substances from a liquid mixture - Figure 2 shows a cross section of a pressure reducing valve according to a first embodiment - Figure 3 shows a cross section of a the pressure reducing valve according to a second embodiment. Figure 1 illustrates a process for degassing certain substances in low-boiling liquid mixtures in closed cooling systems. Line 1 belongs to a liquid system for cooling.

A subset of the liquid is separated from the system 1 by means of a line 2 for degassing and where degassed liquid is returned to the closed liquid system by means of a line 9.

According to said patent, a subset is diverted from the closed system where entry pressure reducing valve 3 is caused to lower the pressure of the separated liquid to a predetermined negative pressure. The flow direction of the liquid is indicated by the arrow at the line 2. The pressure-lowered liquid is brought to a degassing tank 4, where degassing of the liquid is brought to take place. The pressure in the degassing tank is made to be low enough for certain substances to leave the liquid in gas phase. The main part of the separated liquid is pressurized with a first pump 5 which returns this part of the liquid to the system via a line 9.

After the degassing tank 4, a second pump 6 is caused to raise the pressure of a small part of the liquid and gas in the degassing tank 4 separated from the line 1 to a sufficiently high pressure for certain substances to condense and thereby dissolve in the liquid while other substances remain in gas phase.

The second pump 6 is brought to pump liquid and gas to a deaeration tank 7 comprising a float deaeration valve 8, through which separated gases flow to the surroundings.

The float deaeration valve is of a suitably known type.

The remaining part of the liquid in the degassing tank 4 is caused by the first pump 5 to be pumped directly from the degassing tank 4 back to the closed system 1.

Said negative pressure and the pressure in the deaeration tank 7 depend of course on which gases are to go into gas phase and thus be separated and which ones it is desired to keep in the liquid mixture. The present invention relates to a pressure reducing valve for a device of the type shown in Figure 1 for degassing certain substances of low-boiling liquid mixtures in closed-liquid systems. The present pressure reducing valve can be used as the pressure reducing valve 3 in Figure 1. intended to flow.

According to the invention, the pressure reducing valve comprises a housing 30; 31 with an inlet 11; 21 and an outlet 16; 26 for the separated liquid.

The pressure reducing valve comprises one in the housing 31; 32 a movable piston 12; 22 arranged to restrict to a greater or lesser extent the supply of the liquid separated from the pressure reducing valve.

A pump is connected downstream of the pressure reducing valve.

A compression spring 14; 24 is arranged to act between the piston 12; 22 one end wall 17; 27 and the house 31; There is further a channel 13; 23 through the piston, which channel connects the inlet 11 of the pressure reducing valve; 21 with the side of the piston 12; 22 facing the said spring 14; 24. The piston is sealed to the inside of the housing by means of o-rings 20; 30 or other equivalent seal. This channel 13; 23 means that the pressure on the surface of the piston facing the spring is the same as the pressure at the outlet 16 of the pressure reducing valve; 26.

According to a preferred embodiment, said spring 14 is; 24 spring force adjustable by said end wall 17; 27 is displaceable relative to said housing 31; 32. According to a preferred embodiment, said end wall is displaceable relative to the housing in that it is threaded in the housing.

According to a first embodiment of the invention, said piston 12 has a channel 33 running perpendicular to the direction of movement of the piston, where the channel 33 in a first position of the piston opens the inlet 11 and outlet 16 of the pressure reducing valve and where the piston 12 covers a part in a second position separate from the first position. of the inlet and / or outlet.

According to a second embodiment of the invention, a needle 32 projecting from said piston 22, the tip end of which is arranged to cooperate with a seat at the inlet 21 of the pressure reducing valve to form a needle valve and by displacing the inlet 21 to a greater or lesser degree when the piston 22 is displaced relative to the housing needle valve. . The needle 32 is sealed to the housing by means of an O-ring 30 or the like located between the side of the spring 22 of the piston 22 and the outlet 26 of the pressure reducing valve.

A channel 19, 29 runs through the housing 31, 32 to the environment on the side of the piston 12; 22 somvetter from said spring. This channel means that the side of the piston facing from the spring has atmospheric pressure.

According to a preferred embodiment, a mechanical actuator 18; 28 through house wall in channel 19; 29, which actuator is arranged to mechanically actuate the piston so that the pressure reducing valve can let more liquid through from the inlet to the outlet, when the actuator is actuated manually.

The operating member in the said first embodiment may be a pin 18 arranged to be able to abut against and press the piston 12 and push it in the direction of the spring.

The operating means in the said second embodiment may be an L-shaped 28 detail device arranged to be able to abut against and press the piston 22 and push it in the direction of the spring.

As an example, the system pressure, ie the pressure upstream of the pressure reducing valve, can be, for example, 0.5 to 6 bar. In this case, for example, the pressure downstream of the pressure reducing valve 10 can be - 0.95 to - 0.6 bar. The system pressure and the lower pressure created by the pressure reducing valve are determined by which compounds and substances are to leave the system in the gas phase.

The function of the pressure reducing valve with respect to the embodiment in Figure 2 is as follows. At start-up, the actuator 18 is pushed in so that the piston 12 allows liquid to flow into the through-pressure reducing valve. Thereafter, said pump sucks the liquid through the outlet 16, whereby a negative pressure is created in the pressure reducing valve. If the system pressure drops, the increase in pressure in channel 13 is proportional to the change in pressure, due to the fact that said pumps have the same flow, and pulls the piston 12 to the left in Figure 2, whereby the throttle in the valve decreases. This causes the pressure to increase on the surface of the piston facing the spring 15 due to the channel 13, the piston 12 moving to the right in Figure 2 and the choke in the valve increasing.

If the system pressure increases, for example as a result of a temperature rise in the liquid mixture, the piston moves to the right in Figure 2, the throttling increasing proportionally to the pressure change due to said pump having the same flow. This means that the pressure on the piston 14 facing the surface 14 decreases as a result of increased negative pressure in the channel 13, whereby the piston moves to the left in Figure 2 and the throttling in the valve decreases.

By adjusting the spring constant of the spring 15, the pressure reducing valve compensates for changes in the system pressure so that the negative pressure created in the pressure reducing valve is substantially constant.

The present invention thus solves the problem mentioned in the introduction.

The function of the pressure reducing valve with respect to the embodiment in Figure 3 is as follows. At start-up, the actuator 28 is pushed in so that the piston 22 and thus the needle valve 32 allows liquid to flow in through the pressure reducing valve. Said pump sucks the liquid through the outlet 26, whereby a negative pressure is created in the pressure reducing valve. If the system pressure decreases, the negative pressure increases proportionally to the pressure change, due to the fact that said pump has the same flow, and pulls the piston 22 to the left in Figure 3, whereby the throttle in the valve decreases. This causes the pressure to increase at the same time as the pressure on the surface of the piston facing the spring 25 increases due to the channel 23, the piston 22 moving to the right in Figure 3 and the choke in the valve increasing.

If the system pressure increases, for example due to a temperature rise in the liquid mixture, the piston 22 moves to the left in Figure 3 due to the negative pressure changing proportionally to the pressure change when said pump has the same flow. This means that the pressure on the surface facing the piston 22 towards the spring 24 increases as a result of the channel 23, the piston moving towards the right-hand figure 3, whereby the throttling in the valve increases. By adjusting the spring constant of the spring 25 and its output force against the end wall 17; 27, the pressure reducing valve can compensate for changes in the system pressure so that the negative pressure created in the pressure reducing valve is substantially constant.

A number of embodiments have been described above. It is obvious to the person skilled in the art that the detailed design of the pressure reducing valve can be varied without departing from its function.

The present invention should therefore not be construed as limited to the above embodiments, but may be varied within the scope of the appended claims.

Claims (6)

A pressure reducing valve for a device for degassing certain substances in liquid mixtures with a low boiling point in closed liquid systems, where a subset of the liquid is separated for degassing and where degassed liquid is returned to the closed system, the pressure reducing valve being arranged on a line in which said subset to flow, characterized in that the pressure reducing valve comprises a housing (31; 32) with an inlet (11; 21) and an outlet (16; 26) for the separated liquid, in that a pump is connected downstream of the pressure reducing valve, arranged to with constant flow sucking liquid through the outlet, in that the pressure reducing valve comprises a piston (12; 22) movable in the housing arranged to to a greater or lesser extent restrict the supply of the liquid separated to the pressure reducing valve by a pressure spring (14; 24) being arranged between the piston (12; 22) an end wall (17; 27) and the housing, in that a channel (13; 23) is present through the piston, which channel connects pressure the inlet (11; 21) / outlet (16; 26) of the ducting valve with the side of the piston (12; 22) facing said spring (14; 24) and of the piston being sealed against the inside of the housing (31; 32). The pressure reducing valve according to claim 1, characterized in that said spring force of said spring (14; 24) is adjustable in that said end wall (17; 27) is displaceable relative to said housing. Pressure reducing valve according to claim 1 or 2, characterized in that said piston (12) has a channel (33) running perpendicular to the direction of movement of the piston, in that the channel in a first position of the piston opens at the inlet (11) and outlet (16) of the pressure reducing valve ) and in that the piston (12) in a second position separate from the first position covers a part of the inlet (11) and / or the outlet (16). The pressure reducing valve according to claim 1 or 2, characterized in that from said plunger (22) is a needle (32) projecting whose tip end is arranged to cooperate with a seat at the inlet of the pressure reducing valve to form a needle valve and by displacing at a 10 of the piston (22) relative to the housing (31) the needle valve restricts the inlet (21) to a greater or lesser degree. The pressure reducing valve according to claim 1, 2, 3 or 4, characterized in that a mechanical actuator (18; 28) runs through the wall of the housing (3132) and is arranged to mechanically actuate the piston (12; 22) to be mechanically pressed in the direction of the spring (14; 24). The pressure reducing valve according to claim 1, 2, 3, 4 or 5, characterized in that said end wall (17; 27) is displaceable relative to the housing (31; 32) by being threaded in the housing.