RU39175U1 - TWO-STAGE MEMBRANE PUMP (OPTIONS) - Google Patents

Abstract

The utility model can be used in vacuum technology for pumping air or process gases, as well as in hydraulic and pneumatic systems for pumping liquid or gaseous media.

The pump comprises a hollow body, consisting of inlet and outlet parts, between which a membrane is fixed, in which at least one hole is made, blocked by an intermediate valve fixed to the membrane, an inlet valve with an electromagnetic actuator is located on the inlet side of the housing, and on the side of the exhaust part of the housing, an exhaust valve with another electromagnetic actuator is placed, while the intermediate valve, which is the anchor of these electromagnetic actuators, is arranged to move e with the membrane in the cavity of the housing, and its opening and closing under the action of said electromagnetic actuator. The pump may not have an exhaust valve actuator. In this case, the exhaust valve is a simple check valve.

Using the present invention will increase the pumping speed, create a higher vacuum at a relatively small technological cost.

Description

The utility model can be used in vacuum technology for pumping air or process gases, as well as in hydraulic and pneumatic systems for pumping liquid or gaseous media.

A pump is known from the prior art, comprising a hollow body, power and control devices in the form of an electromagnetic drive, a valve stem connected on one side to the shutter of the sealing assembly, and on the other hand to an electromagnet armature, an electromagnet coil and a spring (see prospectus of NPF ARGONAVT -TEPLOENERGO "). When you turn on a known valve, i.e. when voltage is applied to the coil of the electromagnet, the armature is pulled into the coil, and the rod with the shutter moves to the “open” state, overcoming the spring force.

A disadvantage of the known technical solution is its low operational characteristics, as well as reliability and durability.

The objective of the utility model is to create a valve that provides a high pumping speed, a higher vacuum at a relatively low technological cost.

The problem is solved in that the pump comprises a hollow body, consisting of inlet and outlet parts, between which a membrane is fixed with its peripheral part, in the central part of which at least one hole is made, blocked by an intermediate valve fixed to the specified central part of the membrane, on the inlet side of the housing, an inlet valve with an electromagnetic actuator is located, and on the side of the outlet part of the housing, an outlet valve with another electromagnetic actuator is located, while the in-person valve, which is the anchor of these electromagnetic actuators, is arranged to move together with the central part of the membrane in the body cavity, and

opening and closing holes or holes in the membrane under the action of these electromagnetic drives.

Moreover, each of the electromagnetic actuators of the inlet and outlet valves consists of a hollow body with a central through hole, hermetically fixed to the corresponding part of the pump housing, a winding located on the outer surface of the drive housing, and a core with a central through hole located inside the housing.

In addition, the inlet valve consists of a valve disc, arranged to overlap at least one hole of the corresponding electromagnetic actuator, and a rod, one end fixed in the Central part of the plate, and the other end partially entering the Central hole of the housing of the specified actuator and core, and spring loaded relative to the drive housing.

In this case, the exhaust valve consists of a valve disc with a central through hole made with the possibility of overlapping at least one hole made in the exhaust part of the pump housing and spring-loaded relative to the housing or core of the corresponding electromagnetic actuator.

An intermediate valve consists of a valve disc with a central hole, along the perimeter of which a valve membrane is fixed on the side of the pump membrane so that it can snap and overlap the hole or holes in the pump membrane when it clicks in the direction of the plate, fixed to the valve membrane in its central part on the plate side the end of the stopper passing through the central hole of the valve disc and having a stop restricting the movement of the valve membrane.

The problem is also solved by the fact that the pump according to the second embodiment comprises a hollow body consisting of inlet and outlet parts, between which a membrane is fixed with its peripheral part, in

at least one opening is made in the central part, which is blocked by an intermediate valve fixed on the specified central part of the membrane, an inlet valve with an electromagnetic actuator is placed on the inlet side of the housing, and a non-return valve is placed on the outlet side of the body in the outlet pipe, when this intermediate valve, which is the anchor of the specified electromagnetic actuator, is configured to move together with the Central part of the membrane in the cavity of the housing, as well as opening Nia and closing the hole or holes in the membrane under the action of said electromagnetic actuator.

The electromagnetic actuator, the intermediate valve and the intake valve are made similarly to the first embodiment.

The exhaust valve includes a valve disc configured to overlap the openings or openings of the exhaust portion of the pump housing and spring-loaded relative to a stop located in the exhaust nozzle.

The problem is also solved by the fact that, according to the third embodiment, the pump comprises a hollow body, consisting of inlet and outlet parts, between which a membrane is fixed with its peripheral part, in the central part of which at least one hole is made, blocked by an intermediate valve fixed from the outlet part of the body on the specified Central part of the membrane, on which from the side of the inlet part of the body is fixed an anchor with a Central hole in which is placed an inlet valve having an electromagnetic actuator, from the outlet of the housing is placed a return outlet valve, the intermediate valve, together with the central part of the membrane anchor and movable in the cavity of the housing and opening and closing the hole or holes in the membrane under the action of said electromagnetic actuator.

The electromagnetic drive of the inlet valve consists of a core fixed to the inlet part of the pump housing with a central through hole, on the outer surface of which the drive winding is located.

The inlet valve consists of a valve disc arranged to overlap a hole made in the valve seat located in the armature hole, and a rod, one end fixed to the plate, the other end of the valve and core entering the hole of the valve seat, and spring-loaded relative to the actuator core, and on the opposite An inlet valve actuator armature is fixed from the valve disc to the end of the stem.

The exhaust valve includes a plate made with the possibility of blocking the holes or openings of the exhaust part of the pump housing and spring-loaded relative to the stop placed in the exhaust pipe.

The intermediate valve consists of a flat diaphragm fixed with its central part in the central part of the pump diaphragm and made with the possibility of overlapping openings or openings in the pump diaphragm.

The utility model is illustrated by drawings. Figure 1 shows the pump according to the first embodiment of the invention. Figure 2 shows the pump according to the second embodiment of the invention. Figure 3 shows a pump according to a third embodiment of the invention. Figure 4 shows the design of the intermediate valve. Figure 5 shows an embodiment of a part of the pump casing. The pump according to the first embodiment of the utility model comprises a hollow casing consisting of an inlet 1 and an outlet 2, between which a membrane 3 is fixed with its peripheral part, in the central part of which at least one hole is made, blocked by an intermediate valve 4 welded to the central part membranes

3. Parts of the housing 1 and 2 are compressed by rings 5, 6, evenly transmitting forces from the mounting group 7, 8, 9, connecting these rings.

Parts of the housing 1 and 2 can be made by stamping thick-walled blanks, as shown in figures 1-3.

They can also be made by stamping thin-walled blanks (figure 5). In this case, the body parts 1 and 2 are each fixed to a massive annular element 66 made of a rigid composite polymer material based on two-component epoxy resins and thermoplastics and having recesses in the shape of the body part 1. A metal ring 67, mounted on an annular element 66, protects it from chips. The central pipe 68, on which the housing part 1 and the annular element 66 are fixed, has an annular protrusion located in the mass of material of the annular element 66 and preventing the housing part 1 from being squeezed and the polymer material disconnected from the housing.

The membrane 3 can be made round or oval in the form of a plate, both with snapping and without snapping, and has a hole or holes in the Central part. Preferably, the membrane 3 is convex, but may be convex-concave in shape. The tightness of the connection of the membrane 3 with the inlet 1 and outlet 2 parts of the housing is provided by seals 10, 11.

On the inlet part 1 of the housing, an inlet valve 12 with an electromagnetic actuator is located, and on the side of the outlet part 2 of the housing, an outlet valve 13c is arranged with another electromagnetic actuator.

The intermediate valve 4 (see figure 4) is made with the possibility of longitudinal movement together with the Central part of the membrane 3 in the cavity of the housing. The intermediate valve 4 consists of a valve plate 14, which is the anchor of these electromagnetic actuators, made of a strong permanent magnet, in the center of which a hole is made, and a valve membrane 15 made with

the possibility of snapping and having a seal 16 around its perimeter. On the surface of the valve membrane 16 in its central part from the plate side, one of the ends of the stopper 17 is fixed, passing through the central hole of the valve plate 14 and having an annular stop on the other of its ends, restricting the movement of the valve membrane 15, not allowing the latter to leave the zone of elastic deformation . The fastening of the membrane 15 to the membrane 3 is performed by welding, in particular, laser. The intermediate valve 4 is attached to the membrane 3 of the pump so that its central axis coincides with the central axis of the valve.

Each of the electromagnetic actuators of the intake and exhaust valves 12, 13 performs both the function of driving these valves and the function of driving the membrane 3 and consists of a hollow body 18, 19 (respectively) with a central through hole having a flange 20, 21 (respectively) for tight fixing with a seal 22, 23 and fasteners 24, 25 on the flange 26, 27 of the corresponding part of the pump housing.

On the outer surface of the housing 18 there is a winding 28 of the intake valve actuator, held by composite flanges 29, 30, between which the seal 31 is placed. The composite flanges are fastened by fasteners 32, for example, in the form of bolts with a Torex head, as well as fasteners 33 Inside the housing 18 is a core 34 with a central through hole.

On the outer surface of the housing 19 is placed a winding 35 of the actuator of the exhaust valve. Inside the housing 19 is a core 36 with a Central hole, held by a nut 37.

The inlet valve 12 consists of a valve disc, which is the actuator armature, along the perimeter of which a seal 38 is located on its surface to block the central opening of the actuator, and a stem 39, one end of which is fixed in the central part of the valve disc 12, and the other

the end of the actuator and the core 34 partially entering the central hole of the actuator body 18. A spring 40 is put on the rod 34, one end of which abuts against the inner surface of the actuator housing 18, and the other an annular stop 41, made, for example, in the form of a nut at the end of the rod 39.

The exhaust valve 13 consists of a valve disc, which is the armature of the exhaust valve actuator 19 with a central through-hole, along the perimeter of which on its surface from the side of the electromagnetic valve 19 of the exhaust valve there is a seal 42 for closing the openings made in the exhaust part 2 of the pump housing. A spring 43 is put on the valve plate 13, one end of which abuts against the exhaust valve actuator core 36, and the other - in the annular stop 44 made on the side surface of the valve plate 13.

The design of the pump according to the second embodiment of the utility model is similar to the design of the pump according to the first, except for the design of the exhaust valve, as well as the absence of an electromagnetic drive of the specified valve.

The exhaust valve (see Fig. 2) consists of a valve plate 45, along the perimeter of which on its surface from the side of the pump housing there is a seal 46 for blocking the central opening of the exhaust part 2 of the pump housing, and a stem 47 fixed in the central part of the plate 45 with the opposite from the side seal 46 and passing through the hole of the hollow sleeve 48 with openings for the passage of gas installed in the cavity of the flange 49 of the outlet part 2 of the housing. A spring 50 is put on the stem 47, one end of which abuts against the outer surface of the plate 45 and the other against the surface of the sleeve 48. The sleeve 48 is screwed into the cavity of the flange 49 and thereby control the force of the seal and the stiffness of the valve.

The design of the pump according to the third embodiment of the utility model is similar to the design of the pump according to the second embodiment, except for the design of the inlet and intermediate valves, as well as the drive of the pump diaphragm.

An electromagnetic actuator (see FIG. 3) of the inlet valve 54 and the pump diaphragm 3 consists of a flange 51 with a central through hole fixed to the flange 52 of the inlet part 1 of the pump housing. In the hole of the flange 51, a core 34 is fixed with a central through hole, on the outer surface of which is located the drive winding 28

On the central part of the membrane 3 from the side of the inlet part 1 of the housing, the armature 53 of the actuator of the membrane 3 is fixed with a central hole in which the inlet valve is located.

The inlet valve 54 consists of a valve disc, along the perimeter of which on its surface from the side of the electromagnetic actuator there is a seal 55 for blocking the central hole made in the valve seat 56 located in the hole of the armature 53 and secured by its peripheral part 57 to the inlet housing flanges 52, 51 parts of the pump and actuator, the stem 58, one end fixed in the Central part of the valve plate 54, and the other end included in the Central hole of the valve seat 56 and the core 34. The spring 59 is fitted with a spring 59, one the end of which abuts against a guide washer 60 with holes fixed between the valve seat 56 and the actuator core 34, and the other against the stop 61, made in the form of a pin fixed to the stem 58. On the opposite end of the valve 54 from the valve stem 54 is an actuator armature 62 intake valve held by a retaining nut 63.

The intermediate valve consists of a flat membrane 64, along the perimeter of which a seal 65 is placed on the side of the pump membrane, and the central part of which is fixed in the central part of the pump membrane 3.

It should be noted that the seals on the inlet and outlet valves may be located differently depending on the purpose of the pump.

When using a pump to produce a vacuum, the seal can be mounted on a valve disc or seat.

When using a pump for pumping clean liquids, there may be no seal at all, and sealing is ensured by the appropriate manufacture of the surfaces of the plate and seat.

When using a pump for pumping gases or liquids, the seal can be installed on both the seat and valve disc.

The pump according to the first embodiment of the utility model is as follows.

In the initial position, the intake valve 12 is closed, the pump membrane 3 is in the upper position, the intermediate valve 4 is open, the exhaust valve 13 is closed. No voltage is applied to the windings of the inlet and outlet valve drives 28, 35.

A voltage of a certain polarity of the 1st level is supplied to the winding 28 of the main drive of the intake valve 12. Current flows through the winding. The force acts on the armature (plate) of the intermediate valve 4, mounted on the membrane 3 of the pump. The armature is repelled from the core 34 of the actuator and acts on the membrane 15 of the intermediate valve 4, which at a certain voltage level clicks and closes the holes in the membrane 3 of the pump. Intermediate valve 4 is closed. In the closed state of the intermediate valve 4, the membrane 15 in itself creates sufficient sealing force on the seal 16.

Increase the voltage of the same polarity supplied to the contacts of the drive winding 28 (voltage of the 2nd level). The force begins to act on the plate of the intake valve 12, which is the drive armature. Overcoming the resistance of the spring 40, the plate moves away from the saddle

valve, opening a hole in the actuator housing. The inlet valve 12 is open.

A voltage of a certain polarity is applied to the winding 35 of the exhaust valve actuator 13. The force begins to act on the plate of the exhaust valve 13, which is the drive armature. Overcoming the resistance of the spring 43, the valve disc 13 moves to the core 36, opening the holes in the housing of the exhaust part 2. The exhaust valve 13 is open.

Increase the voltage of the same polarity supplied to the contacts of the drive winding 28 (voltage of the 3rd level). The force acting on the armature of the drive of the intermediate valve 4 and the membrane 3 of the pump also increases. The membrane 3 is deformed and clicks, occupying a lower position. Intermediate valve 4 is closed.

The inlet volume of the pump increases, creating a vacuum, and through the open inlet valve 12, gas enters the inlet volume, equalizing the pressure in the inlet and pumped volumes.

The outlet volume decreases and the compressible gas leaves the outlet volume through the open outlet valve 13, equalizing the pressure in the outlet volume and the volume into which the evacuation takes place (for example, atmosphere).

The windings 28, 35 of the actuators are no longer energized, as a result of which, under the action of the springs 40, 43, the intake and exhaust valves 12, 13 are closed. All valves are closed. The diaphragm 3 of the pump is in the lower position.

A voltage of reverse polarity of the 1st level is supplied to the winding 35 of the actuator of the exhaust valve 13. A current flows through winding 35. An anchor of the intermediate valve 4 is acted upon by a force pushing it away from the outlet valve actuator core 36. The membrane 15 is deformed and, with a certain force, clicks, opening the intermediate valve 4. The intermediate valve 4 is open.

Reverse polarity voltage of greater -2nd level is applied to the exhaust valve actuator winding 35. The force acting on the anchor of the intermediate valve 4 increases, deforming its membrane 15. The anchor leaves, abutting against the stopper 17, and without further deforming the membrane 15 of the intermediate valve 4, transfers all the force to the membrane 3 of the pump. At a certain level of force, the membrane 3 is deformed and clicks, occupying the upper position.

The inlet volume of the pump decreases, compressing the gas, and the outlet volume increases, creating a vacuum. Through an open intermediate valve 4, gas flows from the inlet volume to the outlet volume, equalizing the pressure therein.

The inlet valve 12 is closed, the diaphragm 3 of the pump is in the upper position, the intermediate valve 4 is open, the exhaust valve 13 is closed. The pump has returned to its original position.

The operation of the pump according to the second embodiment of the utility model is substantially similar to the operation of the pump according to the first embodiment of the utility model, therefore, only differences in operation are provided.

The non-return valve is closed all the time, except for the period when the pump membrane 3, moving from the upper position to the lower one, compresses the gas in the outlet volume, which, creating pressure on the valve plate 45, overcoming the force of the spring 50, opens this valve and flows out of the outlet volume. When the pressure in the exhaust volume drops to a certain level, the exhaust check valve closes. When pressure is applied to the valve, on the other hand, it remains closed.

The operation of the pump according to the third embodiment of the utility model is substantially similar to the operation of the pump according to the second embodiment of the utility model, therefore, only differences in operation are provided.

Inlet valve 54 is closed. The diaphragm 3 of the pump is in the upper position. A voltage of a certain polarity of the 1st level is supplied to the winding 28 of the inlet valve actuator 54. By winding 28

current flows. The force acts on the armature 62 of the intake valve actuator 54, attracting it to the core 34 of the main actuator. The force is transmitted through the anchor nut-holder 63 to the rod 58. With a certain force, the resistance of the spring 59 is overcome, the inlet valve 54 is opened, and then the valve disc 54 moves away from the valve seat 56. Inlet valve 54 is open.

Increase the voltage of the same polarity supplied to the contacts of the drive winding 28 (voltage of the 2nd level). The force acting on the membrane armature 53 of the membrane repels it from the core 34 of the drive. The diaphragm 3 of the pump clicks into the lower position. A vacuum is created in the inlet cavity of the pump, where gas rushes through the open inlet valve 54, equalizing the pressure in the inlet cavity and the pumped volume. Due to a decrease in its volume, an excess gas pressure is created in the outlet cavity, which opens the check valve and leaves the discharge volume into the environment, while the pressure difference remains sufficient to open the discharge valve. Then the exhaust valve closes. Inlet valve 54 is open. Diaphragm 3 pumps in the lower position.

The winding 28 is no longer energized. The armature 62 of the intake valve 54 ceases to be attracted to the core 34 of the actuator and moves away from it under the action of the spring 59. The plate of the intake valve 54 is pressed against the valve seat 56, blocking it. Inlet valve 54 is closed. Diaphragm 3 pumps in the lower position. Applying reverse polarity voltage to the drive winding does not cause the inlet valve 54 to open, but only increases pressure on the seal 55, improving sealing.

A reverse polarity voltage is applied to the drive coil 28. A current flows through winding 28. A force acting on the membrane armature 53 of the membrane attracts it to the core 34 of the actuator. With a certain force, the membrane 3 clicks, occupying the upper position. Inlet

the volume decreases by compressing the gas contained therein, and the discharge volume increases, creating a vacuum. Under the influence of gas pressure, the intermediate valve opens, and gas flows from the inlet volume to the outlet volume, while sufficient pressure is maintained in the inlet volume to open the intermediate valve. Inlet valve 54 is closed. Membrane 3 is in the upper position.

The proposed pump options are technological in their manufacture and allow to obtain high performance characteristics.

Claims (15)

1. A pump containing a hollow body, consisting of inlet and outlet parts, between which a membrane is fixed, in which at least one hole is made, blocked by an intermediate valve fixed to the membrane, an inlet valve with an electromagnetic actuator is placed on the inlet part of the housing and on the outlet side of the housing there is an exhaust valve with another electromagnetic actuator, while the intermediate valve, which is the anchor of these electromagnetic actuators, is movable place the membrane in a body cavity, as well as opening and closing the hole or holes in the membrane under the action of said electromagnetic actuator. 2. The pump according to claim 1, characterized in that each of the electromagnetic actuators of the inlet and outlet valves consists of a hollow body with a central through hole, sealed mounted on the corresponding part of the pump housing, a winding located on the outer surface of the drive housing, and a core with a central through hole located inside the housing. 3. The pump according to claim 2, characterized in that the inlet valve consists of a valve disc, arranged to overlap at least one hole of the corresponding electromagnetic actuator, and a rod, one end fixed in the Central part of the plate, and the other end partially entering into the Central hole of the housing of the specified drive and the core, and spring-loaded relative to the drive housing. 4. The pump according to claim 2, characterized in that the exhaust valve consists of a valve disc with a central through hole made with the possibility of blocking at least one hole made in the exhaust part of the pump housing and spring-loaded relative to the housing or core of the corresponding electromagnetic drive. 5. The pump according to claim 1, characterized in that the intermediate valve consists of a valve disc with a central hole, along the perimeter of which a valve membrane is fixed on the side of the pump membrane so that it can click and overlap the hole or holes in the pump membrane when snapped to the side of the plate, on the valve membrane in its central part from the plate side, the end of the stopper is fixed, passing through the central hole of the valve plate and having a stop restricting the movement of the valve membrane. 6. A pump containing a hollow body, consisting of inlet and outlet parts, between which a membrane is fixed, in which at least one hole is made, which is blocked by an intermediate valve fixed to the membrane, an inlet valve with an electromagnetic actuator is placed on the inlet part of the housing and on the side of the outlet part of the housing, an outlet valve is placed in the outlet pipe, while the intermediate valve, which is the anchor of the specified electromagnetic actuator, is movable e with the membrane in the cavity of the housing, and opening and closing the hole or holes in the membrane under the action of said electromagnetic actuator. 7. The pump according to claim 6, characterized in that the electromagnetic valve of the intake valve consists of a hollow body with a central through hole, sealed mounted on the inlet part of the pump housing, a winding located on the outer surface of the drive housing and a core with a central through hole located inside corps. 8. The pump according to claim 7, characterized in that the inlet valve consists of a valve disc, arranged to overlap at least one hole of the electromagnetic actuator, and a rod, one end attached to the plate, and the other end partially entering the Central hole the drive housing and the core and spring-loaded relative to the drive housing. 9. The pump according to claim 6, characterized in that the exhaust valve includes a valve disc made with the possibility of blocking the holes or openings of the exhaust part of the pump housing and spring-loaded relative to the stop placed in the exhaust pipe. 10. The pump according to claim 6, characterized in that the intermediate valve consists of a valve disc with a central hole, along the perimeter of which a valve membrane is fixed on the side of the pump membrane with the possibility of its snapping and with the possibility of overlapping holes or holes in the pump membrane when the valve membrane is snapped towards the plate, on the valve membrane in its central part from the plate side, the end of the stopper is fixed, passing through the central hole of the valve plate and having an emphasis restricting the movement of the meme brane valves. 11. A pump containing a hollow body, consisting of an inlet and outlet parts, between which a membrane is fixed, in which at least one hole is made, blocked by an intermediate valve, mounted on the side of the outlet part of the body on a membrane on which from the inlet side An anchor with a central hole is fixed in the housing, in which an inlet valve with an electromagnetic actuator is placed, and a return outlet valve is placed on the outlet side of the housing, while the intermediate valve together with the membrane th and the anchor are made with the possibility of movement in the cavity of the housing and opening and closing holes or holes in the membrane under the action of the specified electromagnetic drive. 12. The pump according to claim 11, characterized in that the electromagnetic drive of the intake valve consists of a core fixed to the inlet part of the pump housing with a central through hole, on the outer surface of which the drive winding is located. 13. The pump according to item 12, wherein the inlet valve consists of a valve disc, arranged to overlap the holes made in the valve seat located in the hole of the armature, and a rod, one end fixed to the plate, the other end included in the hole of the seat valve and core and spring-loaded relative to the core of the actuator, and at the opposite end of the valve stem from the valve stem, an inlet valve actuator armature is fixed. 14. The pump according to claim 11, characterized in that the exhaust valve includes a plate made with the possibility of overlapping the holes or openings of the exhaust part of the pump housing and spring-loaded relative to the stop placed in the exhaust pipe. 15. The pump according to claim 11, characterized in that the intermediate valve consists of a flat membrane fixed by its central part in the central part of the pump membrane and configured to block openings or openings in the pump membrane.