Double membrane for a dust pump

Abstract

A double membrane for a diaphragm pump for fluidizing, covering and conveying dusty products, such as, for example, pulverized coal, with the aid of an inert gas at pressures of up to 7 MPa, the diaphragm pump having a porous, curved loosening element made from aluminum, monitors and ensures the membrane tightness by designing the double membrane with an integrated pressure sensor for monitoring leakages. A hermetically tight separation between the hydraulic chamber and dust chamber of the diaphragm pump can therefore be ensured and damage to the membrane can be promptly identified. Complicated repair and cleaning measures of the entire dust system or hydraulic system in the event of membrane damage are prevented and the tightness of the membrane is maintained during the incident. Particular refinements relate to the composition of the individual membranes and the interaction thereof.

Claims

1. A membrane, comprising: a pressure-resistant housing comprising pressure-resistant first and second half shells; a flange connection connecting the first and second half-shells to each other in a gas-tight manner; a double membrane fastened and clamped within the first and second half-shells; and a loosening face fastened and clamped within the second half-shell via the flange connection; wherein the double membrane comprises a first elastic layer and a second elastic layer, between which a medium lies; wherein the medium is operatively connected to a pressure sensor for leak monitoring; and wherein the loosening face is constructed in layers from porous material in a lower region and from solid material in a region of the flange connection, the loosening face comprising a third half-shell and a gas space being disposed between the second half-shell and the loosening face.

2. The membrane pump as claimed in claim 1, wherein the double membrane has a flange edge for flange-connecting within the flange connection.

3. The membrane pump as claimed in claim 1, wherein the medium is provided by way of a coupling liquid.

4. The membrane pump as claimed in claim 1, wherein the first elastic layer is formed by way of an elastomer, and the second elastic layer is formed by way of a solid PTFE mixture.

5. The membrane pump as claimed in claim 1, wherein the double membrane is guided by way of a central guide rod.

6. The membrane pump as claimed in claim 1, wherein the loosening face contains at least one of annular elements and punctiform support elements.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The sole FIGURE shows a membrane pump according to the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

(2) In the following text, the invention will be described as an exemplary embodiment in greater detail to an extent which is required for comprehension, using the sole FIGURE.

(3) The membrane pump which is shown in the sole FIGURE is an apparatus which consists of two pressure-tight half shells (1, 12) and are connected to one another in a gas-tight manner via a flange connection (2). In addition to a simple dismantling option of the dust pump, the flange connection has the additional function of fastening and clamping the membrane (3) and the loosening face (5) via a filter flange (4). Therefore, by way of the spherical geometry, an advantageous deflection of the membrane into the dust space can take place in the form of a rotational paraboloid, which deflection is gentle for the filter material. Here, the deflection of the membrane is brought about by way of an action of force of the hydraulic liquid, such as described in DE102016201182. Abrupt changes are avoided and, after conclusion of the discharging operation of the membrane pump, largely flat bearing of the membrane (3) against the half shell-shaped loosening face (5) can be achieved. A small dead volume can be achieved by way of said advantageous design, which leads to a minimum dust space volume (10) with at the same time a high conveying quantity and a small high pressure gas loss. In order to avoid undesired movements and folds during the discharging operation, the movement of the membrane is guided and stabilized via a guide rod (9). In one particularly advantageous embodiment, the guide rod can undertake additional tasks, such as a positional determination of the membrane via metrological position transmitters.

(4) Furthermore, the invention is based on the problem of producing dense phase conveying, described in DE 102005047583, by way of generation of a swirl layer within the dust space. This is ensured during the charging and discharging operation by homogeneous gas feeding via a half shell-shaped loosening face (5) of gas-permeable configuration. Porous metal, for example aluminum, with a sufficiently small pore size and filter fineness of <20 m is used as filter material for the loosening face (5). This can ensure that very fine dust particles do not penetrate into the loosening face during the expansion operation. For the production of porous metal, liquid metal, for example aluminum, is poured together with granulated salt into a half shell mold. Salt has a substantially higher melting point, for example, in comparison with metals such as aluminum, and does not pass into the liquid material phase, but rather is distributed uniformly in the molten material. After solidification of the metal, the salt is rinsed out with the aid of a salt-dissolving liquid, and porous and gas-permeable metal is produced. One advantage of said method consists in the possibility of carrying out machining before rinsing out of the salt crystals. Smearing of the pores is ruled out as a result. The required porosity and filter fineness are set via the size of the salt grains.

(5) In one special refinement of the invention, the hydraulic half shell (1) has a smaller internal diameter than the internal diameter of the dust half shell (12). The curved loosening face (5) can be fixed by way of said structural measure.

(6) In order to achieve an advantageous flange seal (2), the loosening face (5) can be configured as a half shell with a flange edge in a manner which is formed in two layers, as a porous metal in the lower region and made from solid material in the flange region.

(7) In one special refinement of the invention, the half shell-shaped casting mold of the loosening face (5) is augmented with additional annular and/or punctiform supporting elements (8). In this way, the half shell-shaped loosening face (5) which consists of porous metal can be fitted and fastened into the lower pressure-tight half shell (12) which consists of solid material. A gas space 13 is advantageously produced between the loosening face which consists of porous metal and the pressure-tight half shell, which gas space 13 can be used for the distribution of the loosening and charging gas. The feeding and discharging of the loosening and charging gas take place via openings 6 in the lower pressure-tight half shell 12.

(8) In the case of a hydraulically driven membrane pump for pneumatic high pressure conveying of fluidized dusts, particular importance is attached to the reliable sealing of the dust space from the hydraulic space which are separated by way of the membrane. The deflection of the membrane and the associated intake and discharging of the particulate material to be conveyed is achieved by way of the hydraulic liquid being pushed in and out in the hydraulic space which is situated above the membrane. In the context of said conveying operation, the penetration of dust into the hydraulic liquid or of hydraulic liquid into the dust space is associated with considerable plant malfunctions and would lead to complex repairs.

(9) In the case of an embodiment of the membrane 3 as a double membrane, two elastomeric membranes (first and second elastic layers 3a, 3b) are arranged such that they are supported mechanically against one another, in such a way that a closed intermediate space containing a medium 3c which can be monitored by means of a pressure sensor p (14) is formed between the membranes. During malfunction-free operation, the intermediate space is at a pressure which is lower than the pressure in the hydraulic space or the dust space. If a pressure rise is then determined in the intermediate space, a leak of one of the two membranes of the double membrane is indicated. The two membranes can be arranged such that they are supported mechanically against one another in a punctiform manner by virtue of the fact that a layer of balls is arranged between them. The two membranes can be arranged such that they are supported mechanically against one another by virtue of the fact that a coupling liquid which is operatively connected to the pressure sensor p is introduced between them.

(10) The elastomeric membrane can be formed by way of an elastomer or a solid PTFE mixture. In the case of the double membrane, one of the two membranes can be produced by way of an elastomer and the other of the two membranes can be produced by way of a solid PTFE mixture.

(11) The invention is also produced by way of a membrane pump for fluidizing and conveying dusts, in the case of which membrane pump the pressure-tight housing of the dust pump consists of two half shells which are connected by way of a flange connection and into which a membrane and loosening face are flange-connected, the loosening face is configured in layers from porous material in the lower region and solid material in the region of the flange connection, the loosening face is configured as a half shell, comprises supporting elements, and a gas space exists between the pressure-resistant lower half shell and the loosening face.

(12) For illustrative purposes, the present invention has been described in detail using specific exemplary embodiments. Here, elements of the individual exemplary embodiments can also be combined with one another. The invention is therefore not to be restricted to individual exemplary embodiments, but rather are restricted merely by way of the appended claims.

LIST OF DESIGNATIONS

(13) 1. Pressure-tight upper half shell, hydraulic half shell 2. Container flange 3. Membrane 3a. First elastic layer 3b. Second elastic layer 3c. Medium 4. Filter flange 5. Loosening face consisting of porous metallic filter material 6. Openings for charging and conveying gas, gas pipe 7. Inner pipe for inlet and outlet of the dust, dust pipe 8. Annular, punctiform, strip-shaped supporting elements 9. Membrane guide/guide rod 10. Dust space 11. Hydraulic space 12. Pressure-tight lower half shell, dust half shell 13. Gas space 14. Pressure sensor p