RU2706662C1 - Disk filter sector element, plate and drain connector for it - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to vacuum disc filters intended for separation of liquid and particles suspended therein and can be used in ore dressing processes. Sector element comprises a plate and a drain connector, connected to each other by mutually complementing contact surfaces. Plate of sector element of disk filter has two parallel to each other side surfaces and small end surface, which in operational position of plate faces the side of disk filter. Side surfaces of the plate are formed by external surfaces of side walls made of water-permeable porous ceramics and arranged so that between their inner surfaces there is a sealed gap. On the edge section of the plate adjacent to its small end surface there is a recess having a surrounding contact surface, through which a sealed gap is opened. Female contact surface intersects with both lateral surfaces and with a small end face surface to form an open gap in a small end surface. Female contact surface is characterized by the fact that there is a section of female contact surface made parallel to side surfaces, which has a section on which the secant straight line perpendicular to the straight line, which connects the ends of this section, crosses this section more than once. Drain connector comprises appropriate male contact surface.

EFFECT: strength of fixation of drain connector on plate with provision of compactness of sector element in axial direction of disk filter.

18 cl, 11 dwg

Description

Technical field

[1] The invention relates to the field of vacuum disk filters designed to separate liquid and particles suspended in it, and can be used in ore dressing processes.

BACKGROUND OF THE INVENTION

[2] A disk filter, the operating principle of which is widely known, contains a number of filter disks mounted on a rotating shaft, each of which is formed by several sector elements. Each sector element contains a sector element plate, the side walls of which are made of porous permeable ceramic, and a sealed internal cavity is formed between the side walls. When a sector element plate passes through a bath with pulp, a vacuum is created in the plate cavity, which, together with the capillary effect characteristic of porous ceramics, causes the liquid to leak into the plate cavity, from where the liquid enters the drainage system of the disk filter and is removed.

[3] During the lifting of the sector element plate from the bath, on the outer surfaces of its side walls there remains a layer of adhering particles, which is a dehydrated concentrate - cake, which, when it is above the bath, is dried under continuous vacuum. Then, using special scrapers, the cake is cleaned onto the conveyor and removed as a finished product of the filtering process. After that, excess pressure of air or liquid is fed into the cavity of the plate of the sector element in order to clean the pores - the so-called backwash, and then the described cycle is repeated again.

[4] In patent publication RU2205057C1, 05.27.2003, a sector element is disclosed in a plate of which a cylindrical connecting hole is made on its end face facing the axis of the disk filter and runs parallel to the outer surfaces of the side walls and connects the plate cavity to the external environment. The first nozzle of the nozzle is inserted into the connecting hole, while the nozzle also contains a second nozzle connected to the hose of the drainage system, through which a vacuum is created and the liquid is sucked out. Thus, this design of the fitting, which performs the function of a drainage connector, allows for a tight connection of the hose of the drainage system to the sector element plate, forming a single closed loop from the inside of the drainage system and the sector cavity of the sector element plate.

[5] The configuration described above is characterized by compactness in the axial direction of the disk filter, however, it also has a number of significant drawbacks. First, the diameter of the first nozzle of the fitting is naturally limited by the thickness of the plate of the sector element, which is small. Accordingly, the area of the passage section of the first nozzle pipe is small compared with the area of the passage section of the cavity of the plate of the sector element. This circumstance creates a significant difference between the pressure in the first nozzle of the nozzle and the pressure in the cavity of the plate of the sector element, which in turn reduces both the efficiency of creating a vacuum for filtration and the efficiency of creating excess pressure to clean the pores.

[6] Secondly, with a possible external impact on the second nozzle pipe directed perpendicular to the side walls of the plate, the first nozzle pipe reproduces the force on the fastening portion of the side wall of the plate surrounding the first pipe. Since the diameter of the first nozzle is small, the area of action of this force is small, respectively, the pressure on the mounting portion of the side wall of the plate is significant. To ensure the strength of the plate with respect to the described effects, the thickness of the fastening portion of the side wall of the plate is increased, which at a given plate thickness leads to a further decrease in the diameter of the first nozzle of the nozzle, exacerbating the problems associated with the pressure drop.

[7] Thirdly, when conducting backwashing, increased pressure in the cavity of the plate exerts a pushing effect on the nozzle, which, upon repeated cyclic repetition, can violate the tightness of the connection between the first nozzle of the nozzle and the plate.

[8] The above-described disadvantages of the sector element disclosed in patent publication RU2205057C1 are mainly eliminated in the sector element disclosed in patent publication WO2014108602A1 and which is a prototype of the invention. Here, the cylindrical connecting hole passes through the side stacks of the plates perpendicular to their outer surfaces and at some distance from the end surface. Therefore, the connecting hole is not rigidly limited in diameter, which allows to ensure a sufficient value of the passage section of the drainage connector inserted into it.

[9] In addition, the drainage connector has a large contact area of its fasteners, resting both on the sections of both outer surfaces of the side walls and on the inner surfaces of the connecting hole located along the thickness of the side walls, which significantly reduces the pressure on the fastening sections of the side walls when exposed to external force. Further, the buoyancy force during backwash is balanced by the fasteners of the drain connector, resting on the opposite outer surfaces of the side walls and having a reliable screw connection to each other. Thus, this configuration allows both to ensure a sufficient value of the bore in the drainage connector, and to preserve the strength of the plate in the place of its connection with the drainage connector.

[10] However, in this configuration, the drainage connector increases the size of the sector element in the axial direction of the disk filter, which may complicate the installation of the sector element in the working position or require additional structural solutions. In addition, the fluid flow here undergoes a double change of direction at a right angle, which increases the hydraulic resistance and reduces the filtering efficiency. It should also be noted the complexity of the design of this drainage connector in terms of ensuring the tightness of the fastening between each other of its fasteners.

[11] The aim of the invention is the creation of a sector element of a disk filter, in which the strength of the side walls of the plate at the junction with the drainage system of the disk filter is provided without increasing the axial dimension of the sector element and without changing the direction of fluid flow.

SUMMARY OF THE INVENTION

[12] To achieve this goal, the present invention is implemented through three objects of the invention.

[13] The first object of the invention is a plate of a sector element of a disk filter having two side surfaces parallel to each other and a small end surface, which in the operational position of the plate faces the shaft of the disk filter. The lateral surfaces of the plate are formed by the outer surfaces of the side walls made of permeable porous ceramics and located so that between their inner surfaces there is a sealed gap. At the edge of the plate adjacent to its small end surface, a recess is made having a female contact surface through which the sealed gap opens. The female contact surface intersects with both side surfaces and the small end surface to form an open gap in the small end surface. The female contact surface is characterized by the fact that there is such a section of the female contact surface made parallel to the side surfaces, which has a section in which the secant line, drawn perpendicular to the line connecting the ends of the given section, crosses this section more than once.

[14] In the particular case of the first object of the invention, the female contact surface is formed by a parallel shift of the generatrix of a straight line along the guide line, while the guide line lies in a plane parallel to the side surfaces of the plate. In the most preferred case, the guide line is at least partially an arc of a circle. It is also preferred if the generatrix extends perpendicular to the side surfaces of the plate.

[15] A second aspect of the invention is a drainage connector of a sectorial element of a disk filter, comprising a patch element and an insertion element connected to each other. The patch element has a patch contact surface made in the form of a flat surface. The insertion element has a male contact surface and an open surface. A through hole is made in the insertion element, the longitudinal axis of which extends parallel to the contact surface, and the first end of the through hole opens through the male contact surface, and the second end through the open surface. The male contact surface is characterized in that there is such a section of the male contact surface made parallel to the patch contact surface, which has a portion in which a secant line drawn parallel to the axis of the through hole intersects this section more than once.

[16] In the particular case of the second object of the invention, the male contact surface is formed by a parallel shift of the generatrix of a straight line along the guide line, the guide line lying in a plane parallel to the patch contact surface. In the most preferred case, the guide line is at least partially an arc of a circle. It is also preferable if the generatrix of the straight line extends perpendicular to the plane of the patch contact surface.

[17] In another particular case of the second aspect of the invention, the insertion element is provided with an end element that has an outer surface forming said open surface and two end contact surfaces facing the male contact surface and located on both sides of the through hole perpendicular to the contact surface.

[18] In another particular case of the second aspect of the invention, the patch element is the first patch element, and the patch contact surface is the first patch contact surface. The connector is provided with a second patch element having a second patch contact surface and configured to connect to the plug element so that the second patch contact surface is parallel to the first patch contact surface. The insertion element and the second overhead element may be provided with complementary positioning elements.

[19] In another particular case of the second object of the invention, the through hole near its second end is threaded. In this case, the connector may be provided with a connecting pipe screwed into the through hole from its second end.

[20] In the particular case of the second object of the invention, corrugation is performed on one or more contact surfaces included in the group of a covered contact surface, both end contact surfaces, both contact surfaces, on the surface. In the preferred case, the corrugation is performed on all contact surfaces of the drain connector.

[21] In another particular case of the second aspect of the invention, the plug-in element and the second patch element are adapted to be connected to each other by screw connection.

[22] A third aspect of the invention is a sectorial disk filter element comprising a plate made in accordance with any of the foregoing embodiments of the first subject matter and a drain connector made in accordance with any of the foregoing embodiments of the second subject matter. In this case, the drainage connector is attached to the plate so that its male contact surface is adjacent to the female contact surface of the recess of the plate.

Brief Description of the Drawings

[23] The implementation of the invention will be explained with reference to the figures:

FIG. 1 is a general view of a sectorial element of a disk filter made in accordance with a third aspect of the invention;

FIG. 2 is a general view of a sector element plate made according to a first aspect of the invention;

FIG. 3 is an enlarged view of section A of FIG. 2;

FIG. 4 is a perspective view of a plate of a sector element, made according to the first object of the invention, with a display of the internal structure;

FIG. 5 is a general view of a drainage connector made in accordance with a second aspect of the invention;

FIG. 6 is a general view of the drainage connector of FIG. 5, when viewed from front to bottom;

FIG. 7 is a general view of a second patch member for a drain connector made in accordance with a second aspect of the invention;

FIG. 8 is a view of the drainage connector of FIG. 5 in sections aa and bb;

FIG. 9 is a view of a connecting pipe for a drainage connector made in accordance with a second aspect of the invention;

FIG. 10 is a perspective view of a drain connector made in accordance with the most preferred case of the second aspect of the invention;

FIG. 11 is a side view of a drainage connector made according to the most preferred case of the second aspect of the invention.

The implementation of the invention

[24] The implementation of the invention will be shown in the best-known examples of the invention, which are not restrictions on the scope of protected rights.

[25] A disk filter sector element 1, a general view of which is shown in FIG. 1 includes a plate 10 and a drain connector 100.

The design and technical results of the first object of the invention

[26] The plate 10 (Fig. 2, Fig. 4) contains two parallel side surfaces 20 and 40, as well as a small end surface 70, a large end surface 80 and two radial end surfaces 81 and 82. The small end surface 70 in the operating position of the plate 10 is turned towards the shaft of the disk filter, the large end surface 80 is turned in the opposite direction, and the radial end surfaces 81 and 82 extend in the radial direction and connect the small end surface 70 to the large end surface 80.

[27] The radial end surfaces 81 and 82 are made flat, and the large end surface 80 is made in the form of an arc of a circle. In turn, the small end surface 70 contains two flat sections 71 and 72, which are in a plan view arranged symmetrically to each other with respect to the axis of symmetry of the plate with the formation of an angle open towards the large end surface 80.

[28] The side surfaces 20 and 40 of the plate 10 are formed by the lateral outer surfaces 21 and 41 of the side walls 22 and 42, respectively, while there is a sealed gap 30 between the inner surface 25 of the side wall 22 and the inner surface 45 of the side wall 42. In this example, a small 70 , large 80 and radial end surfaces 81 and 82 of the plate 10 are formed by the end outer surfaces 23 and 43 of the side walls 22 and 42, respectively. Note that the positions 23 or 43 are the same positions for all end outer surfaces of the corresponding side walls 22 and 42.

[29] In the region of its end outer surface 23, the side wall 22 has edge portions 24 indicated by a single position, the thickness of which is greater than the thickness of the side wall 22 in the region of its inner surface 25. Similarly, in the region of its end outer surface 43, the side wall 42 has edge sections, indicated by a single position 44, the thickness of which is greater than the thickness of the side wall 42 in the region of its inner surface 45. The edge sections 24 and 44 of the side walls 22 and 42 are closed, resulting in an adhesive placed between they provide the fastening of the side walls 22 and 42 to form the plate 10, as well as sealing the gap 30. The closed edge sections 24 and 44 of the side walls 22 and 42 form the edge sections 11, 12, 13, 14 of the plate 10, located near respectively small 70, large 80 and radial end surfaces 81 and 82 of the plate 10.

[30] In the sealed gap 30 there are intracavitary walls 31 extending between the inner surfaces 25 and 45 perpendicular to the side surfaces 20 and 40 of the plate 10. In this case, each intracavitary wall 31 is formed by a pair of interconnected sections of the intracavitary wall (individually in FIG. 4), which protrude from the side of each of the inner surfaces 25 and 45. Between the portions of the intracavitary wall constituting a pair to form the intracavitary wall 31, glue is placed for a stronger fastening the side walls 22 and 42 to each other.

[31] The intracavitary walls 31 form channels 32 for the flow of the filtrate. The sealed gap 30 itself communicates with the outer space through the mouth 34. Although the configuration of the intracavitary walls 31 and channels 32 is not the subject of the present invention, it should be noted that their location is determined in order to minimize hydraulic losses during filtrate flow to the mouth 34, i.e. to the outside of the sealed gap 30.

[32] Thus, one part of the area of each of the side surfaces 20 and 40 of the plate 10, located opposite the inner surfaces 25 and 45 of the side walls 22 and 42, represents the working part involved in the filtering process. The other part of the area of each of the side surfaces 20 and 40 of the plate 10, located opposite the edge sections 11, 12, 13, 14 and intracavitary walls 31, is technological. This part of the area mainly performs technological functions of fastening the side walls 22 and 42, sealing the gap 30, and also forming its optimal internal configuration.

[33] The side walls 22 and 42 are made of permeable porous ceramics, preferably alumina ceramic with the addition of aluminosilicates. At the same time, in the particular case of the implementation of the plate 10 between the side walls 22 and 42 can be enclosed in a polymer honeycomb structure that facilitates the plate 10, made to a predetermined size. This configuration does not prevent the achievement of the primary effects of the first object of the invention.

[34] In this case, portions of the intracavitary walls protruding from each of the inner surfaces 25 and 45, as well as the edge portions 24 and 44 of the side walls 22 and 42, are supported by the honeycomb structure. Corresponding to each other sections of intracavitary walls, together forming any intracavitary wall 31, are fastened together and with a honeycomb structure using glue placed in those cells that overlap these sections of intracavitary walls.

[35] In a similar manner, the edge sections 24 and 44 of the side walls 22 and 42 are fastened together to form the edge sections 11, 12, 13, 14 of the plate 10. It should be noted that in this case a small 70, a large 80 and radial end surfaces 81 and 82 plates 10 are only partially formed by the end outer surfaces 23 and 43 of the side walls 22 and 42. However, another part of these end surfaces is formed by the surface of the adhesive covering the honeycomb structure from the side of the end outer surfaces 23 and 43 and sealing the gap 30.

[36] The edge portion 11 of the plate 10 adjacent to the small end surface 70 has an increased width in the direction of the sealed gap 30, compared with the edge portions 12-14. Holes 15 are made in the edge portion 11 for mounting fasteners that secure the sector element on the disk filter shaft. A waterproof coating can be applied to the side surfaces 20 and 40 of the plate 10 in the region of the edge portion 11 to prevent air inflow through areas not immersed in the pulp bath.

[37] At the edge portion 11 of the plate 10 adjacent to the flat portion 72 of its small end surface 70, a recess 90 is made over the entire thickness of the plate 10. The recess 90 has a female contact surface 91 that extends to the mouth 34 of the sealed gap 30, i.e. ., in other words, through the female contact surface 91, the sealed gap 30 opens outward. Note that the thickness of the plate 10 is equal to the distance between the side surfaces 20 and 40. In addition, the small end surface 70 may not have flat sections 71 and 72, but, for example, be cylindrical. In this case, to perform the recess 90, it is advisable to choose the portion of the small end surface 70 that has the least curvature.

[38] The female contact surface 91 intersects with both side surfaces 20 and 40 and the small end surface 70 to form an open gap 92 in the small end surface 70. The intersection line 93 of the female contact surface 91 and the side surface 20 (hereinafter, the recess intersection line 93 ) has a section 98, on which the secant line 94, drawn perpendicular to the line 95 connecting the ends of the recess intersection line 93, intersects the recess intersection line 93 twice (Fig. 3).

[39] This means that the region of the plate 10 located between section 98 and the small end surface 70 will prevent free passage of the recess of the insert element 110 of the drain connector 100 in the direction perpendicular to the small end surface 70. It should be noted that in the assembled state of the sector element 1 the female contact surface 91 is adjacent to the male contact surface 111 of the insertion element 110 of the drain connector 100, i.e. essentially in contact with it through the adhesive layer.

[40] Thus, the indicated embodiment of the recess 90 ensures the fastening of the drainage connector 100 not only by means of adhesive bonding or other screw-nut fasteners, but also by the body of the plate 10. At the same time, the presence of an open gap 90 in the small end surface 70 provides the possibility of the output of the connecting pipe 150 of the drainage connector 100 out through the small end surface 70. This, in turn, allows for the compactness of the sector element 1 in the axial direction of the disco th filter, and to provide a rectilinear flow of the fluid, reduces the hydraulic losses, which is impossible in the prior art invention.

[41] It should be noted that in this case, the intersection line 93 of the recess coincides with any section of the female contact surface 91 made parallel to the side surfaces 20 and 40. According to conventional terminology, the section of the female contact surface 91 is understood to be the line of intersection of the female contact surface 91 with a secant plane , which is a plane parallel to the side surfaces 20 and 40.

[42] At the same time, in order to achieve the above technical results, the intersection line 93 of the recess does not have to coincide with the cross section of the female contact surface 91. For example, U-shaped chamfers and the like can be made on the side surfaces 20 and 40 along the recess. closed to the small end surface 70, which means that the intersection line 93 of the notch will also take the form U, through which it is impossible to draw a line 94 that could intersect the intersection line 93 of the notch more than once. However, regardless of the shape of the intersection line 93 of the recess according to the invention, there is such a section of the female contact surface 91 made parallel to the side surfaces 20 and 40, which has a section 98, on which the secant line 94, drawn perpendicular to the line 95 connecting the ends of this section, crosses this section more than once.

[43] As for the female contact surface 91, in this embodiment, it has a cylindrical shape, i.e. formed by a parallel shift of the generatrix of a straight line along a guide line lying in a plane parallel to the side surfaces 20 and 40 of the plate 10. The guide line here coincides with the intersection line 93 of the recess and is an arc of a circle, and the generatrix of the straight line runs perpendicular to the side surfaces 20 and 40 of the plate 10. However, this is not a limitation.

[44] For example, the generatrix line may extend obliquely to the lateral surfaces 20 and 40 of the plate 10, which will provide an increased area of the female contact surface 91 and, accordingly, more efficient bonding of the insertion element 110 of the drain connector 100. For example, the guide line may differ from the arc circles, and represent a polygon, oval, wavy line, etc. or a combination of these figures. Then, the cross section 98 of the female contact surface 91 may include more than two intersections of the secant line, in which case the plug-in element 110 of the drain connector 100 will be better held in the direction of the small end surface 70.

[45] Furthermore, the female contact surface 91 may generally differ from the cylindrical surface. For example, it can be a conical surface, which will also allow to increase the area of the surrounding contact surface. It is also possible to make the female contact surface 91 in the form of a hyperboloid surface or a surface consisting of two conical surfaces connected by small bases, or another similar surface. In this case, the plug-in element 110 of the drainage connector 100 consists of two parts that are connected after installation in the recess 90, and the female contact surface 91, if necessary, includes an additional surface that allows the formation of an open gap on the small end surface 70.

The design and technical results of the second object of the invention

[46] The drain connector 100 (Figs. 5-11) is for connecting a sector element 1 of a disk filter to a drain system of a disk filter. The drain connector 100 includes an insertion element 110 and an attachment element 130, which are connected to each other. In this case, the plug-in element 110 and the patch element 130 are integral.

[47] The patch element 130 has a patch contact surface 131 made in the form of a flat surface. The insertion element 110 has a male contact surface 111 and an open surface 112. A through hole 120 is made in the insertion element 110, the longitudinal axis 125 of which extends parallel to the contact surface 131. The first end 121 of the through hole 120 opens through the male contact surface 111, and the second end 122 - through an open surface 112.

[48] The shape of the first end 121 of the through hole 120 corresponds to the shape of the mouth 34 of the sealed gap 30 of the plate 10 and provides minimal hydraulic resistance for the fluid at the inlet to the drain connector 100. The shape of the second end 122 of the through hole 120 is a circle, with the portion of the through hole 120 near its second end 122 is in the form of a cylinder. Since the shape of the first end 121 of the through hole 120 may be different for different cases of the shape of the mouth 34 of the sealed gap 30 of the plate 10, the longitudinal axis 125 of the through hole 120 means the longitudinal axis of the section of the through hole 120 near its second end 122.

[49] In the area near its second end 122, the through hole 120 is provided with a thread for securing the connecting pipe 150 (Fig. 9), to which, for example, with the help of clamps, a hose for the drainage system of the disk filter is connected. It should be noted that the connecting pipe 150 can be fixed in the through hole 120 from the side of its second end 122 and in another way, for example, by fitting in an interference fit with or without adhesive joint. In addition, the connecting pipe 150 and the insertion element 110 can be made integral.

[50] The male contact surface 111 is designed to contact the female contact surface 91 and is made in full accordance with the female contact surface 91 to be adjacent to it. Therefore, all the features of the female contact surface 91 are inherent in the male contact surface 111, taking into account the relationships described below. In addition, since the technical results achieved by the drain connector 100 are manifested when used together with the plate 10, all the technical results described above for the plate 10 and obtained as a result of the recess 90 described above are also valid for the drain connector 100.

[51] For the male contact surface 111, there is such a section made parallel to the patch contact surface 131 that has a portion 119 (FIG. 5), on which the secant line 113, drawn parallel to the axis 125 of the through hole 120, crosses this section more than once.

[52] Thus, as an analogue to the secant plane of the female contact surface 91 drawn parallel to the side surfaces 20 and 40, in the case of the male contact surface 111, a secant plane drawn parallel to the contact surface 131 is used. As an analogue of the secant line 94 intersecting the section of the female contact surface 91 and drawn perpendicular to the straight line 95 connecting the ends of the section line 93; in the case of the male contact surface 111, a secant line 113, The behavior parallel to the axis 125 of the through hole 120.

[53] For the shape of the male contact surface 111, all the shape options described for the female contact surface 91 are valid. In the preferred case, the male contact surface 111 is formed by parallel shearing a straight line along the guide line, the guide line lying in a plane parallel to the contact surface 131 In the case shown in FIG. 5 to 11, the guide line is an arc of a circle, and the generatrix of the straight line runs perpendicular to the plane of the surface of the contact surface 131.

[54] We also note that if the male contact surface 111 of the drain connector 100 is adjacent to the female contact surface 91 of the plate 10, then the first end 121 of the through hole 120 of the drain connector 100 is exactly opposite the mouth 34 of the sealed gap 30 of the plate 10. Thus, to accurately position the first end 121 of the through hole 120 of the drain connector 100 relative to the mouth 34 of the sealed gap 30 of the plate 10, it is sufficient to position the male contact surface 111 and covering the contact surface 91 adjacent to each other.

[55] In the present case of the drainage connector 100, the insertion element 110 is provided with an end element 140, which has an outer surface 143 forming said open surface 112. The end element 140 also has two end contact surfaces 141 and 142 (FIG. 6) that face male contact surface 111 and are located on both sides of the through hole 120 perpendicular to the patch contact surface 131.

[56] The end contact surfaces 141 and 142 allow, in addition to the male contact surface 111 and the patch contact surface 131, to increase the total contact area of the drain connector 100 with the plate 10. Since in this configuration all contact surfaces are for adhesive bonding, increasing the contact area increases the reliability of fixing the drainage connector 100 on the plate 10. We also note that when inserting the element 110 with the end element 140, an additional adhesive layer is disposed between the end contact surfaces 141 and 142 and the small end surface 70, helps to ensure the tightness of the connection of the drain connector 100 and the plate 10.

[57] In addition, when a force is applied to the connecting pipe 150 in a direction parallel to both the side surfaces 20 and 40 of the plate 10 and its small end surface 70, the end contact surfaces 141 and 142 take on the bulk of this force, transmitting it on the small end surface 70 in the direction perpendicular to it. It should be noted that in the direction perpendicular to the small end surface 70, the plate 10 is able to absorb a relatively large load. Since the specified force is distributed over the entire area of the end contact surfaces 141 and 142, the magnitude of such a force that can cause damage to both the plate 10 and the drain connector 100 is significantly increased.

[58] In the present case of the drain connector 100, the patch 130 is the first patch 133, and the patch contact 131 is the first patch contact 134 (FIGS. 6, 10, 11). In this case, the drain connector 100 is provided with a second patch element 135 (FIGS. 7, 10, 11) having a second patch contact surface 136 and configured to connect to the plug element 110 so that the second patch contact surface 136 is parallel to the first patch contact surface 134 .

[59] The second patch element 135 is fixed to the insertion element 110 after the insertion element 110 is inserted into the recess 90 of the plate 10. The second patch contact surface 136 further increases the contact area of the drain connector 100 and the plate 10 with a corresponding strengthening of their bonding to each other by means of glue. It should also be noted that the second patch element 135 provides additional sealing of the connection of the drain connector 100 and the plate 10 on the opposite side from the first patch element 133.

[60] Furthermore, when a force is applied to the connecting pipe 150 in a direction perpendicular to the side surfaces 20 and 40 of the plate 10, the patch contact surfaces 134 and 136 take up the bulk of this force, transferring it to the side surfaces 20 and 40 in a direction perpendicular to them direction. those. in the direction in which the plate 10 is capable of absorbing a relatively large load. Since the indicated force is distributed over the entire area of the contact surfaces 134 and 136, the magnitude of such a force that can cause damage to both the plate 10 and the drain connector 100 increases significantly.

[61] The second attachment member 135 is secured to the insertion member 110 by screw connection 137 in addition to the adhesive joint. Using a screw connection 137 to secure the second patch member 135 to the insert member 110 allows both the first patch contact surface 134 and the second patch contact surface 136 to be pressed firmly against the side surfaces 20 and 40, respectively. This solution allows for the efficiency of gluing the first and second false contact surfaces 134 and 136 to the side surfaces 20 and 40, respectively.

[62] It should be noted that the screw connection 137 can be made as a screw-nut connection, as shown in FIG. 10 and 11, and in the form of one or more screws that are screwed into the internal thread made in the body of the insert element 110.

[63] For ease of mutual positioning, the insertion element 110 and the second patch element 135 are provided with complementary positioning elements 138 and 139, respectively. While the positioning elements 138 of the insertion element 110 are made in the form of grooves, and the positioning elements 139 of the second patch element 135 are made in the form of ridges, the length, width and shape of which correspond to the corresponding parameters of the said grooves.

[64] In the drain connector 100 on the male contact surface 111, the end contact surfaces 141 and 142, as well as the patch contact surfaces 134 and 136, the corrugation 132. The corrugation 132 allows to increase the area of the adhesive joint from the side of the drain connector 100 and increase the bond strength of the drain connector 100 and plates 10. In addition, the implementation of corrugation 132 on the contact surfaces of the drain connector 100 allows you to place an excessive amount of glue near them, which ensures tightness the connecting portion of the contact of the drain connector 100 and the plate 10.

[65] It should be noted that corrugation 132 can only be performed on some of the above contact surfaces. Note also that on all or some contact surfaces of the plate 10 in contact with said contact surfaces of the drain connector 100, corrugation can also be performed, or these contact surfaces may have an increased roughness.

[66] Various polymers may be used to make the drain connector 100, however, it is preferable to use a polyamide, in particular glass-filled polyamide.

The design and technical results of the third object of the invention

[67] The disk filter sector element 1 comprises a plate 10 and a drain connector 100. The drain connector 100 is inserted into a recess 90 of the plate 10 so that its male contact surface 111 is adjacent to the female contact surface 91 of the plate 10 and the first end 121 of the through hole 120 located opposite the mouth 34 of the sealed gap 30. In addition, the first patch contact surface 134 is adjacent to the portion of the side surface 20, the two end contact surfaces 141 and 142 are adjacent to the respective etstvuyuschimi small end surface portions 70 and the second bill contact surface 136 is located adjacent the side surface portion 40.

[68] Between each contact surface of the drain connector 100 and a corresponding portion of the surface of the plate 10, an adhesive layer is applied to securely fasten the drain connector 100 on the plate 10. It should be noted that as for bonding the side walls 22 and 42 to each other when receiving the plate 10, and for fixing on the plate 10 of the drainage connector 100, in the preferred case, structural adhesive based on epoxy resins with inert fillers is used. Additional mechanical fixation, as well as an increase in bonding efficiency, is provided by screw connection 137.

[69] The technical results achieved using the sector element 1 are a combination of the technical results achieved using the plate 10 and the drain connector 100.

Claims (27)

1. The plate sector element of the disk filter having two parallel to each other side surfaces and a small end surface, which in the operational position of the plate faces the shaft of the disk filter, moreover the lateral surfaces of the plate are formed by the outer surfaces of the side walls made of permeable porous ceramics and located so that between their inner surfaces there is a sealed gap, while on the edge portion of the plate adjacent to its small end surface, a recess is made having a female contact surface through which a sealed gap opens, and the female contact surface intersects with both side surfaces and the small end surface with the formation of an open gap in the small end surface, and, the female contact surface is characterized by the fact that there is such a section of the female contact surface made parallel to the side surfaces, which has a section in which the secant line, drawn perpendicular to the line connecting the ends of the given section, crosses this section more than once. 2. The plate according to claim 1, in which the female contact surface is formed by a parallel shift of the generatrix of a straight line along the guide line, while the guide line lies in a plane parallel to the side surfaces of the plate. 3. The plate according to claim 2, in which the guide line is at least partially a circular arc. 4. The plate according to claim 2, in which the generatrix of the straight line runs perpendicular to the side surfaces of the plate. 5. A drainage connector comprising connected to each other overhead element and an insertion element, and the patch element has a patch contact surface made in the form of a flat surface, and the plug-in element has a male contact surface and an open surface, wherein a through hole is made in the insertion element, the longitudinal axis of which extends parallel to the contact surface, and the first end of the through hole opens through the male contact surface, and the second end through the open surface, the male contact surface is characterized by the fact that there is such a section of the male contact surface made parallel to the patch contact surface, which has a section in which the secant line, drawn parallel to the axis of the through hole, crosses this section more than once. 6. The connector according to claim 5, in which  the male contact surface is formed by a parallel shift of the generatrix of a straight line along the guide line, the guide line lying in a plane parallel to the contact surface patch. 7. The connector according to claim 6, in which the guide line is at least partially a circular arc. 8. The connector according to claim 6, in which the generatrix of the straight line extends perpendicular to the plane of the patch contact surface. 9. The connector of claim 5, wherein the corrugation is performed on the male contact surface. 10. The connector according to claim 5, in which the insertion element is provided with an end element that has an outer surface forming said open surface and two end contact surfaces facing the male contact surface and located on both sides of the through hole perpendicular to the contact surface. 11. The connector according to claim 10, in which the corrugation is performed on the end contact surfaces. 12. The connector according to claim 5, in which the patch element is the first patch element, and the patch contact surface is the first patch contact surface, wherein the connector is provided with a second patch element having a second patch contact surface and configured to connect to the plug element so that the second patch contact surface is parallel to the first patch contact surface. 13. The connector according to claim 12, in which the insertion element and the second patch element are provided with complementary positioning elements. 14. The connector according to claim 12, in which at least one patch contact surface is made corrugation. 15. The connector according to claim 12, in which the insertion element and the second patch element are made with the possibility of connection with each other using a screw connection. 16. The connector of claim 5, wherein the through hole near its second end is threaded. 17. The connector according to claim 5 or 16, which is equipped with a connecting pipe fixed in the through hole from the side of its second end. 18. Sector element of a disk filter containing a plate according to any one of paragraphs. 1-4 and a drainage connector according to any one of paragraphs. 5 to 17, wherein the drainage connector is attached to the plate so that its male contact surface is adjacent to the female contact surface of the recess of the plate.

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