KR101372680B1 - Steam ejector for self controlling - Google Patents

Abstract

The present invention relates to a self-controlled steam ejector which discharges mixed steam to a discharge steam pipe by supplying motive steam and sucking suction steam through a driving nozzle with a motive steam pipe and a valve cone, and which has: a valve stem formed at one side of the valve cone, having a valve spring at one side thereof, and having a diaphragm valve at the end part thereof; and a pressure pipeline transmitting the pressure of the mixed steam and connecting the diaphragm valve to a certain point at the outlet of the discharge steam pipe, wherein the valve cone connected to the diaphragm valve is driven by the pressure of the mixed steam discharged from the discharge steam pipe so that the opening degree of the driving nozzle can be controlled, and has spiral grooves at the surface thereof so that vortices can be generated in the supplied motive steam. A self-controlled steam ejector according to the present invention maintains the amount of discharged steam even if the pressure of motive steam is varied, and increases the amount of suction steam against the amount of the motive steam by increasing frictional force between the motive steam and the suction steam sucked thereby, wherein the frictional force is increased by the generation of vortices. [Reference numerals] (AA) Motive steam; (BB) Suction steam

Description

Steam Ejector for Self Controlling

The present invention relates to a self-controlled steam ejector, and more particularly, to adjust the opening amount of the driving nozzle according to the pressure of the mixed steam discharged from the diffuser of the steam ejector so as to discharge a certain amount of the mixed steam, It relates to a self-controlled steam ejector for controlling the opening amount of the drive nozzle by using.

The ejector is a device that ejects a high pressure fluid to a nozzle and compresses and transports a low pressure fluid to a higher pressure through exchanging momentum with a low pressure gas around the jet. Ejector is composed of nozzle, mixing part and diffuser. Since it is a fluid machine that does not have any rotating part or active part in ejector device, it has less trouble and has the feature of compressing or transporting a large amount of fluid even though it is small. .

The steam ejector is an ejector using steam, and the driving fluid of the primary nozzle blows steam to suck gas using the suction force, and the mixed gas of steam and gas is discharged through the diffuser. Such a steam ejector typically supplies driving steam at a constant steam pressure, for example, 11 kg / cm 2, through a driving steam engine, and when the driving nozzle is opened to a certain area, the driving steam sucks suction steam to about 10 kg / m 3. The mixed steam is discharged, and the mixed steam pressure is about 5 kg / cm 2 at a predetermined point of the discharge steam pipe.

However, when the pressure of the driving steam fluctuates and rises above 12 kg / cm 2 depending on the situation of the driving steam generating source, if the opening amount of the driving nozzle is kept the same as before the pressure fluctuation, the suction amount to suck the suction steam also increases rapidly. The mixed air discharged in excess of 10kg / ㎥ and the discharge pressure also exceeds 5kg / ㎠.

In this way, when the supply pressure of the driving steam is increased, if the opening amount of the driving nozzle is kept the same as before the driving steam pressure is increased, the mixed air more than necessary is supplied to the heat-use equipment, which causes the intake steam shortage phenomenon. In addition, the temperature of the intake steam is also lowered, so that the temperature of the steam supplied to the heat use equipment is lowered, so that the performance of the heat use equipment is degraded or the heat use equipment cannot be used.

On the contrary, if the driving steam pressure varies from 11 kg / cm 2 to 10 kg / cm 2, if the opening amount of the driving nozzle is kept the same as before the driving steam pressure fluctuation, the suction amount to suck the inhalation steam also decreases rapidly as the pressure of the driving steam decreases. In order to reduce the pressure, the mixed air discharged to the discharge steam pipe falls below 10 kg / m 3 and the pressure drops below 5 kg / cm 2. As a result, a situation arises in which it is impossible to supply the amount of the mixed air necessary for the heat use facility.

In order to solve this problem, the conventional steam ejector connects a pressure regulating valve to a suction chamber with a nozzle, installs a pressure sensor at the outlet of the diffuser, and opens the valve of the pressure regulating valve according to the detected value of the pressure sensor. Although the suction force generated in the suction chamber was controlled by driving control, the electric circuit for electrically connecting the pressure sensor and the pressure regulating valve and the electric or high pressure air source for driving the pressure regulating valve as an inertia pressure regulating valve Since there is a need for an ejector device is expensive, the installation of the device is expensive.

Korean Patent Laid-Open Publication No. 10-2009-0098878, which is another steam ejector for solving the above-described problems, discloses a steam ejector device having a self-powering function only by connecting compressed air, which is shown in FIG. , A steam ejector (1), an air intake duct (3), a pressure sensor (4) disposed in the air intake duct, an electrically actuated valve member disposed in the compressed air duct and capable of regulating the flow of compressed air to the steam ejector (5), the electric supply control electronics 6 capable of operating at least the valve member with respect to the pressure in the air intake duct sensed by the pressure sensor, and the storage battery 7 supplying electricity to the electric supply control electronics. And communicated with the compressed air duct 2 via the charging air duct 9 and driven by the compressed air to generate electrical energy collected in the battery 7 for charging. Is configured to include electricity (8). Therefore, the steam ejector of the prior art also has a problem that the installation is not simple, and because it includes a generator that can charge the storage battery, the device is complicated and expensive to install the device.

The present invention is to solve the above problems, it is possible to simply and automatically control the control of the drive nozzle provided in the steam ejector using the steam pressure generated by the steam ejector itself, without using electric or high pressure air. To provide a self-regulating steam ejector.

In another aspect, the present invention to provide a self-controlled steam ejector that can increase the suction amount of the suction steam by increasing the suction force of the driving steam discharged through the drive nozzle.

In order to solve the above problems, the self-controlled steam ejector of the present invention is a steam ejector for supplying driving steam through a driving nozzle provided with a driving steam engine and a valve cone, suction steam and discharge the mixed steam to the discharge steam engine The valve cone forms a valve stem at one side thereof, installs a valve spring at an outer circumference of the valve stem, and installs a diaphragm valve at one end of the valve stem, and a predetermined outlet point of the discharge steam engine and the diaphragm valve. It is connected to the pressure pipeline for transmitting the mixed steam pressure therebetween, the valve cone connected to the diaphragm valve is driven by the mixed steam pressure discharged from the discharge steam pipe to control the opening degree of the drive nozzle.

The pressure pipe connecting the discharge steam pipe and the diaphragm valve includes a steam pressure pipe to which the mixed steam pressure discharged through the discharge steam pipe acts, and a fluid tank whose fluid level varies according to the pressure of the mixed steam. Connecting a pressure transfer pipe for transmitting the rapeseed pressure according to the fluctuation to the diaphragm valve, the valve spring provided on one side of the valve stem is provided with a control handle for manually adjusting the tension.

In addition, the surface of the valve cone to form a spiral groove to create a vortex in the driving steam supplied. The helical groove is formed from a position separated by a predetermined distance from the position where the valve cone is in contact with the drive nozzle, and the first spiral groove is formed at a first position corresponding to 1/2 of the diameter of the valve cone from one end of the drive nozzle. And a second spiral groove is located at a second position, which is twice the first spiral groove, and a third spiral groove is located at a third position, which is three times the first position, and the width of the first spiral groove is a helical groove. The first position of the valve cone is formed to be 1/10 of the diameter, the width of the second spiral groove is formed twice the width of the first spiral groove, the width of the third spiral groove is 3 times the width of the first spiral groove It is formed in a double, and the depth of each spiral groove is formed to be equal to the width of the first spiral groove.

The present invention transmits the pressure of the discharge steam to the diaphragm valve through the steam pressure pipe, the diaphragm valve is operated in accordance with the pressure of the discharge steam, if the discharge steam pressure is low, the diaphragm valve is reversed, if the discharge steam pressure is high As the pram valve moves forward, the driving nozzle is opened or the opening degree is controlled, and accordingly, the amount of steam discharged can be uniformly controlled by adjusting the amount of driving steam to its own pressure generated by the steam ejector according to the variation of the discharge steam pressure. Effect occurs.

In addition, the present invention by rotating the driving steam discharged along the surface of the valve cone is discharged, by forming the suction steam and the vortex sucked by the driving steam to increase the frictional force of the driving steam and the suction steam to increase the suction steam amount to the driving steam amount This increasing effect occurs.

1 is a conceptual diagram showing a vapor ejector according to the prior art.
2 is a view showing a self-regulating steam ejector according to the present invention.
3 is a view showing the outlet of the discharge steam pipe according to the present invention.
Figure 4 is a view showing a state in which the spring adjustment handle screwed to the valve stem in accordance with the present invention.
5 is a view illustrating a state in which the driving nozzle is opened by the valve spring of the self-regulating steam ejector according to the present invention.
6 is a view showing a spiral groove formed in the valve cone according to the present invention.
7 is a view showing the relationship between the mixed steam pressure and the opening amount (%) of the driving nozzle according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The self-controlled steam ejector according to the present invention is a conventional steam ejector that ejects driving steam through a driving nozzle, sucks inhalation steam, and discharges mixed air, wherein a valve cone for controlling the opening degree of the driving nozzle is adjusted to the pressure of the mixed steam. By controlling the opening amount of the driving nozzle by operating accordingly, even if the pressure of the driving steam is changed, the discharge amount of the mixed steam mixed with the driving steam and the suction steam discharged through the discharge steam pipe is kept constant.

In order to achieve this object, the self-controlled steam ejector 100 of the present invention supplies driving steam through a driving nozzle 10 having a driving steam engine 11 and a valve cone 14 as shown in FIG. 2. In the steam ejector for sucking the suction steam and discharging the mixed steam to the discharge steam engine (13), the valve cone 14 for adjusting the opening amount of the drive nozzle is formed in a conical shape, rod-shaped valve stem on one side (15) to form.

In addition, a valve spring 18 is provided on one side outer circumference of the valve stem 15 to provide reaction force in controlling the opening amount of the valve cone 14 and the driving nozzle 10. Install the diaphragm valve (16) that pushes 15).

In addition, the diaphragm valve 16 is connected between a predetermined point of the outlet of the discharge steam engine 13 and the diaphragm valve 16 by a mixed steam pressure which is discharged from the discharge steam engine 13 by connecting to a pressure pipe that transmits the mixed steam pressure. The valve cone 14 connected to) is driven.

Referring to the configuration of the self-controlled steam ejector according to the present invention in detail, the drive nozzle 10 for discharging the high-pressure drive steam flowing from the drive steam engine (11); A discharge steam pipe 13 into which drive steam discharged from the drive nozzle 10 flows; A suction steam pipe (30) connected between an outlet of the drive nozzle (10) and an inlet of the discharge steam pipe (13); A steam pressure pipe 20 installed at a predetermined outlet (0) of the discharge steam engine 13 to transfer a pressure at an outlet of the discharge steam engine 13; A fluid tank 21 connected to the steam pressure pipe 20; A valve cone 14 installed at the driving nozzle 10 to adjust an opening amount of the nozzle; A valve stem (15) extending from the valve cone (14) and connected to the diaphragm valve film (17) of the diaphragm valve (16); The diaphragm is connected by the fluid tank 21 and the pressure transfer pipe 22 and pressurizes the valve stem 15 according to the pressure of the pressure transfer pipe 22 to adjust the opening degree of the driving nozzle 10. A pram valve 16; A spring adjustment handle (19) for manually adjusting the opening degree of the drive nozzle; It is composed of a valve spring (18) fitted to the valve stem (15) and installed between the outside of the driving steam engine (11) and the spring adjustment handle (19) to apply a return force to the valve stem (15).

The driving nozzle 10 discharges the high-pressure driving steam introduced from the driving steam engine 11 and at the same time, a valve capable of adjusting the amount of driving steam discharged according to the degree of insertion or withdrawal of the valve cone 14. It is formed into a sheet structure.

The high-pressure driving steam supplied to the inlet of the driving nozzle 10 is ejected through the driving nozzle 10 to lower the pressure. That is, while the pressure is lowered at the outlet side of the drive nozzle 10, the suction steam is sucked from the inlet steam pipe 12 connected to the outlet of the drive nozzle 10, and the mixed steam in which the drive steam and the suction steam are mixed is discharged steam pipe ( 13) flows into.

As the mixed steam introduced into the discharge steam engine 13 is rapidly reduced in kinetic energy, the pressure inside the discharge steam engine 13 is rapidly increased and the speed of the mixed steam is also significantly reduced.

In addition, the steam pressure pipe 20 that delivers the pressure of the mixed steam installed at the outlet predetermined position of the discharge steam engine 13 is fixed in a state where one end penetrates the lower side wall of the discharge steam engine 13 and protrudes to a certain height. . The vapor pressure tube 20 is connected to the fluid tank 21 to be installed. The fluid tank 21 is filled with the fluid at a constant level, and the fluid level of the fluid may rise or fall according to the vapor pressure of the outlet of the discharge steam pipe 13. The fluid here is preferably water.

The other side of the fluid tank 21 is installed by connecting the pressure transfer pipe 22, and the pressure transfer pipe 22 is connected to one end of the diaphragm valve 16 to pass through. Accordingly, when the fluid level of the fluid contained in the fluid tank 21 rises or falls by the pressure of the mixed vapor discharged through the discharge steam pipe, the fluid filled in the pressure transfer pipe 22 is the diaphragm valve 16. Pressing or releasing the pressing force of the diaphragm valve membrane 17 is to be made.

In more detail with respect to the supply of the driving steam and the discharge of the mixed steam, if the driving steam is supplied to the driving nozzle 10 at a constant pressure through the driving steam engine 11, the driving steam sucks the suction steam and discharge steam ( Through 13). The mixed steam in which the driving steam discharged to the discharge steam engine 13 and the suction steam are mixed forms a predetermined pressure, and the mixed steam pressure thus formed is transmitted through the steam pressure pipe 20 installed in the discharge steam pipe.

When the pressure of the mixed steam acts on the steam pressure tube 20, the fluid level of the fluid tank 21 installed on one side of the pressure steam pipe is lowered, and the fluid in the pressure transfer pipe 22 connected to the fluid tank 21 is pressurized to cause a diaphragm valve ( 16). When the pressing force is applied to one side of the diaphragm valve membrane 17 by the pressure of the fluid supplied to the diaphragm valve 16, and the pressing force acts to exceed the elastic reaction force of the valve spring 18, the diaphragm by an excessive amount The valve cone 14 enters the driving nozzle 10 by reducing the opening degree of the driving nozzle by moving the ram valve membrane 17 to push the valve stem 15 connected to the other side of the diaphragm valve membrane 17.

On the contrary, when the pressing force is lower than the elastic reaction force of the valve spring 18, the diaphragm valve membrane 17 is retracted and moved by the amount less than the valve stem 15 connected to one side of the diaphragm valve membrane 17. The retracted valve cone 14 entering the driving nozzle 10 is separated to increase the opening degree of the driving nozzle.

For example, as shown in FIG. 3, the mixed steam pressure 5kg / cm <2> passing through the fixed point 0 of the discharge steam pipe is set as a reference pressure. At this time, the driving nozzle 10 is maintained so that half of the total open area is opened. Subsequently, the steam pressure pipe 20 detects a state in which the mixed steam pressure is increased or decreased, and the changed pressure is applied to the diaphragm valve for opening and closing the driving nozzle to control the amount of driving steam passing through the driving nozzle. Allow the amount of mixed steam to be increased or decreased.

As shown in FIG. 3, when the mixed steam pressure and the driving nozzle opening amount are the mixed steam pressure of 5 kg / cm 2, the valve spring tension of the diaphragm valve is adjusted so that the opening amount of the driving nozzle is 1/2 of the total nozzle opening area. As the mixed steam pressure increases, the opening area of the driving nozzle is reduced at a constant rate to adjust the valve spring tension of the diaphragm valve so that the mixing vapor pressure is reduced to 1/5 of the total nozzle opening area at the mixed steam pressure of 8 kg / ㎠. As the steam pressure decreases, the opening area of the drive nozzle is increased at a constant rate, and the valve spring tension of the diaphragm valve is controlled to increase at a constant rate so that 4/5 of the total nozzle opening area is opened at the mixed steam pressure of 2 kg / ㎠. It is desirable to.

That is, the valve stem 15 and the valve cone 14 connected to the diaphragm valve membrane 17 move left and right in proportion to the outlet mixed steam pressure of the discharge steam engine 13. That is, when the outlet pressure of the discharge steam pipe 13 is lowered, the fluid level of the fluid contained in the fluid tank 21 is increased, and accordingly the pressure of the pressure transfer pipe 22 is lowered to push the diaphragm valve membrane 17. As the pressure of the fluid decreases, the valve spring 18 acts in the left direction returned by the elastic force.

As shown in FIG. 4, the spring adjustment handle 19 is screwed to the valve stem 15. Rotating the spring adjustment handle to pressurize or relax the spring tension of the valve spring (18) mounted on the outer periphery of the valve stem.

As shown in FIG. 5, when the valve cone 14 is pulled to the left, the length of the valve cone 14 inserted into the driving nozzle 10 is shorter than before (indicated by the dashed line), thereby driving the nozzle 10. As the open area of the gas increases, the driving steam passing through the driving nozzle 10 increases, so that the outlet pressure of the discharge steam engine 13 increases again.

When the outlet pressure of the discharge steam pipe 13 is increased, the fluid level of the fluid contained in the fluid tank 21 is lowered. As a result, the pressure in the pressure transfer pipe 22 is increased so that the diaphragm of the diaphragm valve 16 is increased. The valve membrane 17 is pushed to the right.

At this time, when the force pushing the diaphragm valve membrane 17 to the right side overcomes the elastic force of the valve spring 18, the valve stem 15 and the valve cone 14 are also pushed to the right and inserted into the driving nozzle 10. As the length of the valve cone 14 is increased (more inserted), the open area of the drive nozzle 10 is reduced, so that the outlet pressure of the discharge steam engine 13 is reduced again.

Accordingly, the valve stem 15 and the valve cone 14 connected to the diaphragm valve membrane 17 move left and right according to the outlet pressure of the discharge steam pipe 13 so that the valve cone 14 drives the driving nozzle 10. It will automatically adjust the degree of opening.

In this case, when the spring adjustment handle 19 is turned, the valve spring 18 is pushed to the right to compress, but when the elastic force of the valve spring 18 is stronger than the pressure of the diaphragm valve 16, the valve stem 15 and the valve cone 14 ) Is pushed to the left side so that the valve cone 14 is pulled out of the driving nozzle 10, so that the opening area of the driving nozzle 10 is increased.

As a result, the driving steam passing through the driving nozzle 10 increases, so that the outlet pressure of the discharge steam engine 13 increases. Likewise, by turning the spring adjustment handle 19 to release the valve spring 18 to the left side, the above can be reversed.

In the steam ejector 100 according to the present invention, a valve cone 14 for controlling the amount of driving steam passing through the driving nozzle 10 is inserted into the driving nozzle 10 and the portion exposed to the steam mixing chamber 31 is sucked. The steam is introduced between the outlet of the driving nozzle 10 and the inlet of the discharge steam engine 13, in which the driving steam and suction steam are mixed by the frictional force.

At this time, in order to increase the frictional force between the driving steam and the suction steam to increase the ratio of the suction steam amount to the driving steam amount by installing a spiral groove on the surface of the valve cone 14, the vortex phenomenon occurs in the driving steam, thereby increasing the friction force It is possible to increase the ratio of the suction steam amount to the driving steam amount.

As shown in FIG. 6, the valve cone 14 according to the present invention passes through the drive nozzle 10 and is exposed to the steam mixing chamber 31 by a predetermined length. As shown in the surface of the valve cone 14 exposed to the steam mixing chamber 31, spiral grooves 14a, 14b, and 14c may be formed to cause vortex phenomena while rotating the driving steam discharged.

The spiral groove is formed in a spiral angle of 30 ° ~ 45 °, starting at a certain distance from the position in contact with the valve cone and the driving nozzle to form a small diameter portion of the valve cone, but the position where the valve cone and the driving nozzle contact Starts forming the first spiral groove 14a at the first position L1 corresponding to 1/2 of the valve cone diameter D, and is formed at the second position L2 which is second from the driving nozzle. The two spiral grooves 14b are formed at a distance corresponding to twice the first position L1, and the third spiral grooves 14c formed at the third position L3, which is the third position from the driving nozzle, are formed in the second spiral groove 14b. It is formed to be located at a distance corresponding to three times the one position (L1).

Further, the width B1 of the first spiral groove 14a is formed to be 1/10 the size of the valve cone diameter D of the portion corresponding to the first position L1, and the width B1 of the second spiral groove 14b is defined. B2) is formed to twice the width of the first spiral groove B1, and the width B3 of the third spiral groove 14c is formed to be three times the width of the first spiral groove B1. Each spiral groove width is formed in a straight line so that no step is formed between the width and the width. That is, the width of the third spiral groove 14c formed at the third position L3 starts to widen from the width B1 of the first spiral groove 14a formed at the narrow first position L1. The width B3 is formed to be maximum.

The depth H of the helical groove formed in the valve cone 14 is equal to the width B1 of the first spiral groove 14a formed in the first position L1.

By forming the spiral grooves 14a, 14b, and 14c on the surface of the valve cone as described above, the spiral is discharged in a spiral form when the driving steam passes through the valve cone in which the spiral groove is not formed. Therefore, the frictional force at the contact surface between the driving steam and the suction steam is increased to increase the ratio of the suction steam amount to the driving steam amount, thereby increasing the mixing ratio. When the mixing ratio is expressed as a numerical value, when driving steam is discharged to a valve cone without a spiral groove, the mixing ratio at the point where the driving steam sucks suction steam and passes the valve cone does not exceed 50%. If the spiral groove of the above-described structure is formed in the same point as the above occurs the effect of mixing the driving steam and the mixed steam more than 80%.

As the mixing rate is increased, a small amount of steam ejector is used to produce a mixed amount of steam in the same way as a larger capacity steam ejector, thereby miniaturizing the size of the steam ejector.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

10: driving nozzle 11: driving steam engine
12: inhalation steam pipe 13: discharge steam pipe
14: valve cone 15: valve stem
16: diaphragm valve 17: diaphragm valve membrane
18: valve spring 19: adjustment handle
20: steam pressure pipe 21: fluid tank
22: pressure transmission pipe 14a to 14c: first spiral groove to third spiral groove
100: self-regulating steam ejector

Claims (4)

In the steam ejector for supplying the driving steam through the driving nozzle provided with the driving steam engine and the valve cone, the suction steam to discharge the mixed steam to the discharge steam engine,
The valve cone forms a valve stem on one side thereof,
Install a valve spring on the outer periphery of the valve stem and a diaphragm valve at one end of the valve stem,
Connect a pressure pipe for transmitting a mixed steam pressure between the outlet point of the discharge steam pipe and the diaphragm valve,
Self-regulating steam ejector, characterized in that the opening of the drive nozzle is controlled by driving the valve cone connected to the diaphragm valve by the mixed steam pressure discharged from the discharge steam engine. The method of claim 1,
The pressure pipe connecting the discharge steam pipe and the diaphragm valve includes a steam pressure pipe acting on the mixed steam pressure discharged through the discharge steam pipe and a fluid tank having a variable oil level according to the pressure of the mixed steam.
Self-regulating steam ejector, characterized in that for connecting the pressure transfer pipe for transmitting the fluid pressure in accordance with the fluctuations in the fluid level of the fluid tank. 3. The method of claim 2,
The valve spring provided on one side of the valve stem is a self-controlled steam ejector, characterized in that the control handle is provided to adjust the tension manually. The method of claim 3,
On the surface of the valve cone is formed a spiral groove so that the vortex is generated in the driving steam supplied,
The helical groove starts from a position separated by a predetermined distance from the position where the valve cone is in contact with the driving nozzle to the discharge steam pipe, and the first spiral groove is located at a first position corresponding to 1/2 of the diameter of the valve cone from one end of the driving nozzle. A second spiral groove is located at a second position, which is twice the first spiral groove, and a third spiral groove is located at a third position, which is three times the first position.
The width of the first spiral groove is 1/10 of the diameter of the first position valve cone where the spiral groove is formed, and the width of the second spiral groove is twice the width of the first spiral groove, and the width of the third spiral groove is The width is formed three times the width of the first spiral groove,
And the depth of each spiral groove is equal to the width of the first spiral groove.

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