RU16527U1 - MEMBRANE HYDRAULIC DRIVE DOSING PUMP - Google Patents

Abstract

ABSTRACT MEMBRANE HYDRAULIC DRIVE DOSING PUMP

The proposed utility model relates to pump engineering, relates to hydraulic diaphragm metering pumps and can be used in various fields of industry, agriculture, utilities and other industries for the dosed supply of various fluids, including aggressive, explosive and fire hazardous, etc., media.

An analogue of the proposed device is a membrane metering pump (see "Description to the operating instructions for a metering machine of type B32, pump certificate of the Bran + Lubbe company V-0150/1, 1981, p. 49), containing a drive and a membrane head in which the air separator is made in the form of a two-seat spring-loaded valve installed inside the tank for the supply of drive fluid (RV). The valve during the suction stroke is closed by a spring, and at the beginning of the discharge stroke under pressure it opens, part of the pancreas, together with air, is discharged through it into the reservoir for the stock of the pancreas, and then the valve closes the upper seat and the pumping stroke occurs. A disadvantage of the analogue is the inability to control the operability of the air separator during the operation of the pump.

The prototype of the proposed device, in which this disadvantage is eliminated, is a membrane hydraulic metering pump (see Patent SU No. 1395851 A1 F 04B43 / 06, 13/00 "Membrane hydraulic metering pump), containing a drive and a membrane head in which the air separator, with the aim to increase the accuracy of dosing, it is made in the form of a tube fixed to the lower end in the housing, with an adjustment screw with holes and a spring-loaded rod passing inside the channel of the upper valve seat, the shut-off element of which is installed It is installed with the possibility of free movement between the lower seat and the stem, and the upper end of the tube is located above the level of the drive fluid and contains a nozzle.

The disadvantage of the prototype is the design complexity of the arrester, as well as the inability to use it for low-flow pumps (0.2 ... 2 l / h). The latter is explained by the fact that with a small pump supply, the amount of ejected liquid through the air separator becomes comparable with a single supply, which sharply reduces the metering accuracy, and in some cases makes normal operation impossible.

The technical task of the proposed utility model is to simplify the design of the pump, increase the accuracy of its dosing and provide the ability to adjust the air separator to the optimal mode when the pump is put into operation and, if necessary, during its operation.

In FIG. 1 shows the design of a hydraulic diaphragm metering pump; in FIG. 2 - air separator.

The pump contains a housing 1, in which, with the formation of the pump 2 and drive 3 chambers, a membrane separator 4 is installed.

The pump chamber 2 is equipped with a suction 5 and pressure 6 valves. The drive chamber 3 is divided by a perforated wall 7. In the housing 1 there is a plunger 8 sealed with a stuffing box 9. The plunger is connected to a drive mechanism (not shown in Fig. 1), which tells it to reciprocate.

A container 10 is attached to the upper part of the housing for the stock of the pancreas. Inside the tank 10 is placed a spring-loaded make-up valve 11 and an air separator 12. If necessary, a safety valve can be installed in it. The container 10 is closed by a lid 13, on which a cap 14 of a transparent material is fixed. The air separator 12 channels 15, 16 is connected to the make-up valve 11 and the drive chamber 3.

the tip 22 at the top. The upper seat 23 of the valve 18 is the edge of the narrowed hole in the nozzle 19, and the lower saddle 24 is the same edge of the nozzle 17. The ball valve 18 is installed with the ability to change the distance between the seats 23 and 24 due to movement along the thread of the nozzle 19 and the elastic the sealing ring 20. Inside the tube 21, the holes of the nozzle 19 and the tip 22, the stem 25 is freely placed, the lower end of which abuts the valve 18, and the upper end is connected to the nozzle 22. The pump operates as follows.

The reciprocating movement of the plunger 8 through the pancreas is transmitted to the membrane separator 4. When the plunger moves in the left arrow (Fig. 1), the pumped liquid is sucked into the chamber 2 from the suction line through valve 5. When the plunger moves to the right, the pumped liquid through valve 6 enters the line injection.

At the end of the suction stroke, the membrane separator 4 rests on the perforated wall 7. In this case, a vacuum is applied in front of the plunger 8 and the make-up valve 11 is activated, automatically feeding the pancreas, the missing volume of liquid, resulting from losses through the sealing device and losses in the air separator.

The air released from the pancreas through channel 16 enters the air separator 12, located at the highest point of the drive chamber 3.

At the beginning of the injection stroke, due to the pressure of the pancreas, the ball valve 18 of the air separator 12 is transferred to the upper seat 23. At this point, a small amount of the pancreas with air through the tube 21 and the tip 22 is thrown into the cap 14 and the exit of the pancreas from the drive chamber 3 is closed, then the stroke injection.

At the beginning of the suction stroke, under the influence of its own weight and the weight of the rod 25, the valve 18 closes.

The amount of RJ thrown out through valve 18 at its predetermined dimensions is controlled by changing the ball’s free play between the seats 23 and 24 by moving the nozzle 19 along the thread. In this case, the optimal operation mode of the air separator is adjusted when the pump is running. The control is carried out visually by the amount of air emission and a small amount of pancreas through the hole in the cap 22, closed by a transparent cap 14.

When starting the diaphragm pump, especially with low feeds, certain difficulties arise due to the air inside the pancreas. The process of removing air from the drive chamber is sometimes delayed for a long time.

The proposed design of the air separator along with the simplicity of the technical solution of its main elements allows you to speed up the preparation of the pump for operation. This is achieved by accelerating the circulation of the pancreas through the make-up valve 11 and the air outlet; the rod 12 by simply holding the air separator valve open with the rod 25 during the discharge process. In this case, the available air in the drive chamber and the pancreas is quickly removed through the air separator 12.

The stated technical problem was solved by simplifying the design of the pump, the air separator of which has a minimum number of parts, it was possible to set it to the optimal operating mode when it was started up the pump and during operation due to the available adjustment of the freewheel of the air separator valve, the pump output to Work mode.

Authors: XI Gryanin

Description

MEMBRANE HYDRAULIC DRIVE DOSING PUMP

The proposed utility model relates to pump engineering, relates to hydraulic diaphragm metering pumps and can be used in various fields of industry, agriculture, utilities and other industries for the dosed supply of various fluids, including aggressive, explosive and fire hazardous, etc., media. Normal operation of the diaphragm hydraulic drive pump can be ensured only by completely removing air from the drive fluid (RV), which is released from it during suction, as well as as a result of its penetration through the seal of the plunger.

During operation of pumps with low feeds and high pressure in the discharge line (more than 10 MPa), the presence of air in the pancreas becomes the main factor determining the dosing accuracy.

Removing air from the pancreas presents a certain difficulty and, to a large extent, depends on the design solutions of the main elements of the pump.

An analogue of the proposed device is a membrane metering pump (see "Description to the operating instructions for a metering machine of type B32, pump certificate of the Bran + Lubbe company V-0150/1, 1981, p. 49), containing a drive and a membrane head in which the air separator is made in the form of a two-seat spring-loaded valve installed inside the tank for the stock of the pancreas. The valve during the suction stroke is closed by a spring, and at the beginning of the discharge stroke, it opens under pressure, part of the pancreas, together with air, is discharged through it into the reservoir for the stock of the pancreas, and then the valve closes the upper seat and the discharge stroke occurs. A disadvantage of the analogue is the inability to control the operability of the air separator during the operation of the pump.

The prototype of the proposed device, in which this disadvantage is eliminated, is a membrane hydraulic metering pump (see Patent SU No. 1395851 A1 F 04B43 / 06, 13/00 "Membrane hydraulic metering pump), containing a drive and a membrane head in which the air separator, with the aim to increase the accuracy of dosing, it is made in the form of a tube fixed to the lower end in the housing, with an adjusting wing with openings and a spring-loaded rod passing inside the channel of the upper valve seat, the locking element of which is installed in the tube It is installed with the possibility of free movement between the lower seat and the stem, and the upper end of the tube is located above the level of the drive fluid and contains a nozzle.

The disadvantage of the prototype is the complexity of the design of the air separator, as well as the inability to use it for low-flow pumps (0.2 .. .2 l / h). The latter is explained by the fact that in it at the beginning of the discharge stroke there is an open channel due to the free-wheeling of the ball valve until it stops against the end of the spring-loaded pusher. Through this channel, a portion of the pancreas is discharged into the reservoir for the stock of the pancreas, and then the discharge stroke occurs when the ball valve overcomes the resistance of the spring-loaded plunger and closes the upper saddle of the air separator. With a small pump supply, the amount of liquid ejected through the air separator becomes comparable with a single supply, which drastically reduces the metering accuracy, and in some cases makes normal operation impossible. The known design of the air separator has a fixed ball valve stroke, which is due to the size of the sleeve located between the valve seats, which does not allow you to adjust the air separator to the optimal operating mode during pump start-up by changing the ball valve stroke.

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air separator to the optimum mode when starting up the pump and, if necessary, during its operation.

Fig. Shows the construction of a hydraulic diaphragm metering pump; in FIG. 2 - air separator.

The pump contains a housing 1, in which, with the formation of the pump 2 and drive 3 chambers, a membrane separator 4 is installed.

The pump chamber 2 is equipped with a suction 5 and pressure 6 valves. The drive chamber 3 is divided by a perforated wall 7. In the housing 1 there is a plunger 8 sealed with a stuffing box 9. The plunger is connected to a drive mechanism (not shown in FIG. 1), which informs it of the reciprocal movement.

A container 10 is attached to the upper part of the housing for the stock of NJ. Inside the tank 10 is placed a spring-loaded make-up valve 11 and an air separator 12. If necessary, a safety valve can be installed in it. The container 10 is closed by a lid 13, on which a cap 14 of a transparent material, for example, plexiglass, is fixed.

The air separator 12 channels 15,16 connected to the make-up valve 11 and the drive chamber 3.

The air separator (Fig. 2) contains a fitting 17, a two-seat ball valve 18, a nozzle 19 screwed into the fitting 17, sealed with a ring 20, and fixed with a nut 27. A pipe 21 is installed on the thread 19 and ends at the top with a tip 22. The upper seat 23 of the valve 18 is the edge of the narrowed hole in the nozzle 19, and the lower seat 24 is the same edge of the hole of the fitting 17. The ball valve 18 is installed with the possibility of changing the distance between the seats 23 and 24 by moving along the thread of the nozzle 19 and deforming the elastic seal nogo ring 20. Inside the tube 21, the openings 19 and nozzle tip 22 is placed freely the rod 25, the lower end of which rests on the valve 18, and the upper nozzle 22, displayed above pump operates as follows.

The reciprocating movement of the plunger 8 through the pancreas is transmitted to the membrane separator 4. When the plunger moves in the left arrow (Fig. 1), the pumped liquid is sucked into the chamber 2 from the suction line through valve 5. When the plunger moves to the right, the pumped liquid through the valve 6 enters the line injection.

At the end of the intake stroke, the membrane separator 4 rests on the perforated wall 7. At the same time, the vacuum in front of the plunger B increases and the make-up valve 11 is activated, automatically feeding the pancreas, the missing volume of liquid, resulting from losses through the sealing device and losses in the air separator.

The air released from the pancreas through channel 16 enters the air separator 12, located at the highest point of the drive chamber 3.

At the beginning of the discharge stroke, due to the pressure of the pancreas, the ball valve 18 of the air separator 12 is transferred to the upper seat 23. At this point, a small amount of the pancreas together with air through the tube 21 and the tip 22 is thrown into the cap 14 and the exit of the pancreas from the drive chamber 3 is closed, then the stroke occurs injection.

At the beginning of the suction stroke, under the influence of its own weight and the weight of the stem 25, the valve 18 closes.

The air trap is adjusted when the pump is running. The control is carried out visually by the amount of air emission and a small amount of pancreas through the hole in the cap 22, closed by a transparent cap 14.

When starting the diaphragm pump, especially with low feeds, certain difficulties arise due to the air inside the pancreas. The process of removing air from the drive chamber is sometimes delayed for a long time.

The proposed design of the air separator along with the simplicity of the technical solution of its main elements allows you to speed up the preparation of the pump for operation. The above is achieved by accelerating the circulation of the pancreas through the make-up valve 11 and the air separator 12 by simply holding the air separator valve in the open state with the help of the rod 25 during the discharge process. In this case, the available air in the drive chamber and the pancreas is quickly removed through the air separator 12.

The stated technical problem was solved by simplifying the design of the pump, the air separator of which has a minimum number of parts, it was possible to set it to the optimal operating mode when it was started up the pump and during operation due to the available adjustment of the freewheel of the air separator valve, the pump output to Work mode.

Authors: f / V f Gryanin

IN AND. Agapov V.A. Podrezov

Claims (1)

Hydraulic diaphragm metering pump containing a drive, a housing with a membrane separator installed in it to form a pump and drive chambers, the latter of which is connected to a reservoir for supplying drive fluid, having a make-up valve and an air separator containing a fitting, a double-seat ball valve, and a tube with a tip drawn above the level of the drive fluid in the tank, characterized in that one of the seats of the ball valve is made in the form of the edge of the hole directly in the fitting, and in ond - a edge of the apertures in the nozzle, interconnected by threads and having end faces between which taken elastic sealing ring, and inside the tube and the nozzle opening arranged rod lower end of which rests on the valve ball and the second displayed above the opening in the tip.