HU211413B - Rotary membran pump for passing fluids and gases - Google Patents

Abstract

The invention relates to a rotary machine for delivering liquids or gases, the invention is a rotary machine for delivering liquids or gases comprising a driving unit (2) coupled with a rotating part (11), a housing (1) provided with suction and delivery openings (5, 7) and a stationary part (3) arranged in said housing (1). The machine according to the invention may be a pump or compressor and is very advantageous among others for pumping corrosive and erodent fluids or compressing gases, wherein, according to the invention, the rotating part (11) is provided with rolls (15) rotatably mounted on shafts (16) arranged radially with respect to the axis of rotation (6) of the machine, said stationary part is an elastic disc (3) provided with channels (8) within said disc (3) and with ribs (25) on the surface facing the rolls (15) along said channels (8), wherein each of the channels are including an angle with the respective radii (R) and one end thereof is connected to the suction opening (7), the other one to the pressure opening (5). The rolls (15) are of conical shape having a greater diameter radially outside than inside and are arranged in uniform distances from each other along a circle coaxial with the axis of rotation (6). The respective heights (h) of the ribs (25) are greater than that of the channels (8) in the same axial directions. The elastic discs (3) preferably consist of two parts (3a, 3b) in axial direction: a support part (3a) at the front wall of the housing and a pressed part (3b) facing the inside of the housing (1), the channels (8) being between these two parts (3a, 3b).

Description

Scope of the description: 6 pages (including 2 sheets)

HU 211 413 B

The present invention relates to a self-absorbing pump type of a circularly operated membrane piston, without a gland, for the delivery of liquids and gases, which can also be used for corrosive materials.

The most commonly used pump types at this time are the rotary swirl pump and the screw pump, as well as the alternate piston and membrane pump type.

A significant quantity of performance is the swirl pump, and the piston pump has a high compression capability, the swirl pump type being relatively low-pressure, while the piston pump has a relatively low delivery capacity compared to the other type, so none of them is quite favorable. its performance characteristics in terms of practical requirements.

Among the other two types of pumps, the diaphragm pump has to be equipped with both structural components and rectifying valves, which are both compliant and alternative, in terms of compression and transport capacity, which is a complex and cost-increasing circumstance. The pulsating nature of flow is also unfavorable.

The diaphragm pump is a rarely used type because of the low performance, the incorporation of the alternating motion components and the flow coordinating valves and the pulsating nature of the flow.

A hollow pump that is not suitable for general quantitative, pressure and lifetime requirements can also be considered a membrane pump-like structure, which is capable of fluid circulation by circulating the rollers which are driven by a flexible hose in a circular arc. With low volume and pressure performance, the disadvantage is the rapid damage of the hose due to excessive material tensions in the bending of the hose edges. Such a solution can be found in e.g. U.S. Pat. patent.

Screw pump type would be suitable for the establishment of proportional small to medium volume and pressure outputs, but could not be significantly compromised due to its complicated, costly design and significant internal friction and, consequently, relatively rapid damage and the use of excess energy.

The unfavorable design and operating characteristics of the screw pump have been summarized in the description of the invention of a rotary piston pump for liquids and gases published under number T / 66377 filed with the National Office of Invention, which relates to the development of a novel, preferred, diaphragm screw pump type.

In the case of a novel screw pump that can be formed with the help of a flexible diaphragm body, the diaphragm body is the most complicated component, therefore it is expected that its bearing capacity will be the determining factor in the spreading and application of the pump type based on practical needs.

Although the diaphragm screw pump design is considered to be very advantageous, it is also expedient to provide another type of diaphragm pump with similarly advantageous, similarly flexible diaphragm element (s), but of a similarly wide range but with a different construction as an alternative to meeting the practical needs even more safely.

It is an object of the present invention to provide a pump with a relatively simple design, a circulating volume displacement self-priming and a favorable power characteristic, which does not include an alternating motion component, and separate valve assemblies, and where sliding movements between the operating surfaces can also be eliminated so that no friction occurs. between the operating parts, which makes the entire plant economically feasible, economically and safely operated, long life scalable and corrosive materials can be used, which, thanks to its favorable characteristics, can also contribute to meeting the environmental aspects.

The present invention accomplishes this objective by a structural arrangement in which circularly rolling elements are subjected to pressure on a flexible disc containing channel cavities, thereby causing separate suction and compression effects in the channel cavities through displacement perpendicular to the axis of the channel cavities, resulting in fluid flow in the radial direction. the vortex pump has an apparent and a piston pump's actual operating mode.

From the point of view of the mode of operation, the structural solution and the performance characteristics, other concrete pumps comparable to the invention have not been known so far.

The operating principle of the pump according to the invention is most comparable to that of a primer roller hose pump, which, however, is not suited to significant demands due to its low power and lifetime.

The present invention is based on the discovery that, in the case of a structural element consisting of one or more discs formed of a material having a large elastic deformation, radially angled channel cavities are formed from the middle portion to the rim so that the outer surface of the disk is thickened along the passage of the attachment cavities. and by attaching a radially arranged tapered roller roller to the surface, a closed compression force is provided by rotating the rollers, enclosed by the surfaces displaced by the rollers, in the cavity cavities, which, in accordance with the movement of the rollers, partially move radially forward. Thereby, gas or liquid delivery can be achieved by volume displacement, with considerable pressure and quantity performance.

All of this is possible because the disk diaphragm, which is partially disc-diaphragm containing channel cavities, is structurally sufficiently rigid to set up and tolerate higher fluid pressures, but is conveniently designed to provide for the movement of the cavity cavities, the spring-moving fluid, and the multiple swirl of the vortex pump. Multiple spring cavity designs allow for large amounts of movement at high speeds, but do not cause deformations that cause overload and rapid fatigue during operation, such as when the flexible hose closes at the edges. you are absolutely overwhelmed.

The principle of operation is without surface friction, which is very good in terms of life and energy consumption.

The roller line can be operated from the conveyed medium in a closed area with a static seal under ideal lubrication conditions. This does not require a gland.

As a result, efficiency can be set high.

With the appropriate selection of the disk diaphragm and housing materials, the pump according to the invention can also be used for the transmission of various chemical and corrosive materials.

The device according to the invention can be considered as a new type of diaphragm pump, the operating principle of which is most similar to that of a hose pump, while the embodiment is closer to the disc valve disc valve. However, achievable performance and lifetime values can significantly exceed the characteristics of these types - with a relatively simple structure.

Typical characteristics of the pump type according to the invention for practical use are:

- circular operating mode,

- Volume displacement, uniform, non-resistive, quantitative transmission,

- gas and liquid transferability, therefore self-absorbing,

- small structural dimensions and weight,

- relatively simple construction,

- solution without gland

- quantitative performance and compression of a favorable proportion; favorable novelty trait

- the transmitted medium does not come into contact with mechanically stressed surfaces,

- there are no friction surfaces,

- economical production, economical and safe operation,

- long life scalability,

- Suitability for conveyance of corrosive and other chemicals.

Based on these, the pump is suitable for general needs, primarily in low and medium volume and pressure ranges, with an environmentally friendly design.

According to its design and function, the invention comprises a housing consisting of a suction and discharge openings, or a housing, including a press disk, a rotatable roller wheel, and a disk diaphragm made of structural material having a high elastic deflection with channel cavities, as well as a structure for forming a force acting on the pressure disc. a rotary pump for transporting fluids and gases directly connected to the drive motor and driven directly by its axis, characterized in that the start and end points of the dowels of the disk diaphragm are connected to separate compartments: suction or compression zones dependent on the direction of rotation of the housing; a disk diaphragm that is closer to the motor; and, on the opposite inner surface thereof, protrusions extending over the height of the attachment cavities, with a total value greater than their height, are attached to this surface by a roller which is pressed by the compression disc and rotated by the drive shaft, which is a hinged or rigidly connected and stiffened inner brain and an outer wreath having conical rollers having an equal diameter to the outer circumference, spaced at equal distance from each other.

An example of an embodiment of the pump according to the invention is illustrated by the longitudinal arrangement of Figure 1. Figure 2 shows a typical sectional view of the disk membrane with the channel cavities. Examples of possible solutions for engaging the disk diaphragm in favor of positive operation are shown in Figures 3 and 4.

The operating parts are housed in a housing mantle 6 attached to the drive motor 18 and in the space bounded by the front panel 5 of the housing connected thereto.

The front panel of the housing 5 comprises a suction port 1 and a pressure nozzle 4. The suction space 2 and the pressure space 3 are connected to the stumps.

The housing 5 is enclosed between the front panel and the housing 6 in the form of a statically sealed, crosslinked material such as e.g. a polyurethane, rubber - made of 7 diaphragm diaphragms, in which the cavity cavities 8 for fluid flow are formed. The inner and outer surfaces of the displaced side of the disk diaphragm 7 along the coupling cavities 8 have outer and inner thickenings 9 and 10 of total size greater than the height of the channel cavities.

The roller wheel 11 is coupled to the disk diaphragm 7 by the rollers 12 operated by the drive motor 18 by means of a rotating disc 13 which is rotated by the drive motor 18, coupled to the drive shaft 16 mounted on the drive shaft 17.

A small compression spring 14 at one end is supported by a pressure spring 14 on the pressure plate 15, while the axially required axial force is provided.

EN 211 413 B pressure is generated by multi-section, high-pitched thread-type coupling during operation due to the relative rotation of the pressure plate 13 on the drive bushing 16 and the associated axial displacement.

Preventing the creation of a greater compression force than necessary, which could be particularly triggered at start-up, is possible by means of a rotation barrier between the driving bushing 16 and the pressure disc 13.

When the drive motor 18 is started, the drive bushing 16, which is wedged to the drive shaft 17, rotates, rotates in an axial direction, and then clamps to the disk diaphragm 7, and then rotates the pressure disc 13, which rolls 12 into the cavity cavities 8 to flow into the coupling cavities 2 from the inlet chamber 2. they are conveyed towards the compression space by closing the coupling cavities 8 through the outer and inner thickenings 9 and 10 passing through them.

In the disk diaphragm 7, excessive local deformations leading to the generation of harmful voltages and thus reducing the longevity are not present during operation. An example of a possible solution of the disk diaphragm 7 is illustrated in FIG.

The disk diaphragm is in this case made of two halves. The outer and inner surfaces 22 of the moving membrane side 19 moved by the rollers 19 to the coupling cavity 8 are curved, and the channel cavity 8 has a cylindrical cross-section due to the formation of a channel surface 23 with a larger curvature half-curved side 20 on the front face of the housing. The two diaphragm halves are joined by a self-sealing fit through the groove / flange design 24/25.

The fit of the supported diaphragm half 20 to the closure of the channel cavity 8 is facilitated by curved reliefs 26 on the support surface on both sides of the channel cavity. This does not cause harmful voltage congestion during operation.

Similarly to the foregoing, the membrane design shown in Figure 4 is composed of two halves and differs from Figure 3 in that inserts 27 are joined to the edges of the channel cavity at both sides of the channel cavity 19 and 20 along their edges farther from the cavity B the rim portion 28 fits into the recesses 29, 30 of the supported supported membrane portions 19, while their endings 31 penetrating into the channel cavity 8 are sharply thinned.

This solution is also advantageous to avoid the formation of extreme deformation stresses.

For the purpose of calculating the performance of the pump according to the invention, for example, a disk diaphragm having a diameter of 100 mm and a Zj = 6 channel cavity, the volume of the channel cavity to be conveniently formed is V = 5 cm ³ .

By using at least z ₂ = 4 rollers and with a n = 48 / s engine, and with a utilization factor of 0.8:

Q = 0.8 Vz, .z ₂ .n / 2 = 0.8.5.6.4.24 = 2500 cm ³ / s = 150 1 / min = 9 m ³ / h, which is a very significant yield.

The compression capacity is theoretically infinite, the safe delimitation of which by limiting the compression force of the pressure disc 13 in a relatively simple manner, e.g. can be achieved by the use of elastic deformable rollers.

Claims (3)

PATENT CLAIMS A pump for circulating liquids and gases, preferably a motor driven by a motor (18) and driven directly by its axis (17), comprising a suction and discharge port (1, 4) and a housing (13). comprising a rotatable roller wheel and a disc diaphragm (7) made of a resilient structural material comprising buckle cavities (8) and structural members acting on the pressure disk (13), characterized in that the channel cavities (8) start and end in separate spaces: connected to the suction and discharge areas (2, 3) of the housing (6) depending on the direction of rotation and to the outer surface (21) of the disk diaphragm (7) closer to the drive motor (18) and the surface (22) of the channel cavities (8) corresponds to their height dimension The projections (9, 10, 21, 22) having a size greater than 10 mm are provided with a roller wheel (11) which is pressed by the pressure disk (13) and rotated by the drive shaft (17), which is provided with a spindle or disc type. having conical rollers (12) spaced radially spaced from one another to an interconnected and stiffened inner hub and outer ring. A pump according to claim 1, characterized in that its disk diaphragm (7) consists of two halves: a moving diaphragm half (19) and a supported diaphragm half (20), the external diaphragm (19) connected to the coupling cavities (8) and the inner surfaces (21, 22) of which are curved and have a greater curvature of the supported diaphragm half (20) on the housing front (5), the two diaphragm halves (24) having a self-sealing flange (24) 25) is connected to one another by means of a configuration and curved reliefs (26) are formed on the supporting surface of the supporting membrane half (20) adjacent to the buckle cavities (8). A pump according to claim 1 or 2, characterized in that grooves (30, 29) are formed in the movable and supported diaphragm halves (19, 20) along the edges of the channel cavities (8), with inserts (27) therein. ) are connected to their peripheral portions (28), the ends (31) of which extend into the channel cavity (8) and are preferably tapered.