RU103341U1 - VALVE FOR VACUUM SEWERAGE SYSTEMS - Google Patents

Abstract

 1. Valve for vacuum sewer systems, including a hollow body, having expanded upper and lower parts, outside the side walls of the body there is a fitting for connecting the valve to the air duct, and elastic ring elements are attached to the edges of the side walls of the body from the top and bottom by outer edges, which can take a flat or conical shape, in the cavity of the body is an elastic cuff of cylindrical shape, the ends of which are attached to the edges of two holes made in the side walls of the body, the valve It is equipped with a clamping mechanism for an elastic cuff, consisting of an upper and lower frame, perpendicular to the axis of the elastic cuff, each of the frames consists of two vertical struts and a horizontal crossbar attached to the struts on one side and a horizontal disk on the other side, while the edges of the disks are fastened with the inner edges of the elastic ring elements, the racks of the upper frame are paired with the racks of the lower frame and connected to the side walls of the housing so that the racks of the frames have the possibility of longitudinal moving relative to each other and vertical moving relative to the walls of the case, each of the frames covers an elastic cuff and contacts the cuff with its crossbar, in addition, a spring is installed between the disk of the upper frame and the crossbar of the lower frame, there are vertical guides on the inner surfaces of the side walls of the case, in which there are the outer edges of the racks of the lower frame, and these vertical guides are formed by intersecting planes, and the edges of the racks of the lower frame located in them

Description

The utility model relates to sanitary equipment, namely to vacuum toilet systems, and can be used, for example, in passenger rail cars.

The prior art.

From the description of the invention to US patent US 3996628 C. 4/26, publ. 12/14/1976 g [1], a valve is known for vacuum sewer systems. The valve of the technical solution [1] has a hollow body in which an elastic sleeve is installed. Opening and closing of the valve is carried out by changing the pressure in the cavity of the valve body. However, the absence of a clamping mechanism for the elastic cuff and, therefore, the need to control the valve only using pneumatics will require a large expenditure of energy, which is undesirable in conditions of vehicles.

From the description of the invention to US patent US 3984080, cl. 251/5, publ. 10/05/1976 g [2], a valve for vacuum sewer systems is known, including a hollow body with an elastic cuff and a cuff clamping mechanism, actuated by changing the pressure in the body cavity. The technical solution [2] cannot guarantee reliability during operation due to the fact that the longitudinal stability of the parts of the pinch mechanism, which are subjected to heavy loads during valve opening and closing operations, is not ensured.

In the description of the invention to US patent US 3732579, cl. 4/41, publ. 05/15/1973 g [3], the design of the valve for vacuum sewer systems is disclosed. The inventors propose to use the so-called solenoid valve. a diaphragm type valve that opens and closes under the action of a vertical rod pressing it on an elastic cuff. The rod is driven by a spring-loaded plunger mounted in a cylinder into which water is supplied under pressure. In the technical solution [3], the draining operation, i.e. the operation of emptying the toilet is tightly connected with the operation of washing it. This solution is characterized by water overruns. In addition, the mechanical impact of the rod can cause rapid wear of the elastic cuff, which will lead to flooding by the sewage of the railway carriage.

When developing the proposed technical solution, the authors were faced with the task of creating a reliable high-speed valve that works using vacuum means and is used to sew toilet toilets into the storage tank of a railway passenger car.

The technical result of this utility model is to increase the reliability of the device while reducing the cost of its operation.

The indicated technical result is achieved in a valve for vacuum sewer systems, including a hollow body having expanded upper and lower parts, outside the side walls of the body there is a fitting for connecting the valve to the air duct, and elastic ring elements are attached to the edges of the side walls of the body from above and below by outer edges , which can take a flat or conical shape, in the body cavity there is an elastic cuff of a cylindrical shape, the ends of which are attached to the edges of two holes, you filled in the side walls of the body, the valve is equipped with a clamping mechanism for the elastic cuff, consisting of upper and lower frames located perpendicular to the axis of the elastic cuff, each of the frames consists of two vertical posts and attached to the posts on one side of the horizontal crossbar, and on the other side - horizontal the disk, while the edges of the disks are fastened to the inner edges of the elastic ring elements, the racks of the upper frame are paired with the racks of the lower frame and connected to the side walls of the housing so that the racks of the frames have the possibility of longitudinal movement relative to each other and vertical movement relative to the walls of the case, each of the frames covers an elastic cuff, and contacts the cuff with its crossbar, in addition, a spring is installed between the upper frame disk and the lower frame crossbar, on the inner surfaces of the side walls the housing has vertical guides in which the outer edges of the racks of the lower frame are located, and these vertical guides are formed by intersecting planes , and the edges of the racks of the lower frame located in them are rounded.

The following particular cases of the utility model execution are provided.

In the middle parts of the disk of the upper frame and the crossbar of the lower frame on the side of the spring, there are elongated vertical protrusions that are located inside the spring and are interconnected with the possibility of vertical relative movement of each other and vertical movement relative to the spring.

In the central part of the disk of the upper frame there is an outer protrusion in which an annular groove is made on the inner side of the housing for installation of the end part of the spring.

The racks of the lower frame have upwardly protruding ends, which are a continuation of these racks and are in contact with the racks of the upper frame, while the aforementioned protruding ends have the ability to move vertically relative to the racks of the upper frame and side walls of the housing.

The side surface of the housing is a surface of rotation.

The side surface of the body is a multifaceted surface.

The side surface of the body is a multifaceted surface with rounded ribs.

The upper and lower walls of the body are attached to the side walls of the body by means of hoops pressing the edges of the upper and lower walls to the edges of the side walls of the body.

The essence of the utility model is illustrated by the following drawings.

Figure 1. General view of the valve in a perspective view, partial section.

Figure 2. Closed view of the valve, vertical axial section.

Figure 3. The same side view.

Figure 4. Type of valve in open state, vertical axial section.

Figure 5. The same side view.

6. A horizontal section along aa in figure 2.

7. Bottom frame, axonometry, scaled up.

Fig. 8. Top frame, axonometry, scaled up.

In the accompanying drawings, the following conventional digital designations of nodes and parts are used.

1. Valve body.

2. Elastic ring elements.

3. Elasticated cuff.

4. The upper frame.

5. The bottom frame.

6. Rack frames.

7. Crossbeams of a framework.

8. Discs frames.

9. The spring.

10. Fitting for connecting the valve to the air duct.

11. Oblong vertical ledge of the upper frame disc.

12. An elongated vertical ledge of the bottom frame.

13. The outer protrusion of the hard disk of the upper frame.

14. The annular groove in the outer protrusion of the disk of the upper frame.

15. The protruding ends of the racks of the lower frame.

16. Vertical guides for the clamping mechanism of the elastic cuff,

As shown in figures 1-6, the valve body 1 is hollow and has extensions in its upper and lower parts. The side walls of the housing 1 are made of hard material, such as plastic. Elastic annular elements 2 are attached to the side walls of the housing 1 from above and below by outer edges, which can take on a flat or conical shape when the valve is operating.

In the cavity of the housing is an elastic cuff 3 of cylindrical shape, the ends of which are attached to the edges of two holes made in the side walls of the housing 1. In the cavity of the housing 1 is a pinch mechanism of the elastic cuff 3. The pinch mechanism includes two frames - the upper frame 4 and the lower frame 5 which are perpendicular to the axis of the elastic cuff 3 and are made of a rigid material, for example plastic. Each of the frames 4 and 5 consists of two vertical posts 6, a horizontal beam 7 and a horizontal disk 8. The crossbar 7 of the lower frame 5 is double. The racks 6 of the upper frame 4 are connected in pairs with the racks 6 of the lower frame 5 and are connected to the side walls of the housing 1 so that these racks of the frames have the possibility of vertical movement relative to each other and the possibility of vertical movement relative to the walls of the housing 1. Each of the frames 4 and 5 covers an elastic cuff 3 and in contact with it with its crossbar 7.

In addition, the components of the pinch mechanism of the elastic cuff 3 include a spring 9, which is installed between the disk 8 of the upper frame 4 and the crossbar 7 of the lower frame 5. A fitting 10 is installed in the side wall of the housing 1 for connecting the valve to the air duct (the air duct is not shown in the drawings shown). In the middle parts of the disk 8 of the upper frame 4 and the crossbar 7 of the lower frame 5 from the side of the spring 9 there are elongated vertical protrusions 11 and 12, which are located inside the spring 9 and are interconnected with the possibility of vertical movement relative to each other and move inside the spring 9. Oblong protrusions 12 of the lower frame 5 are double.

An outer protrusion 13 is made in the central part of the disk 8 of the upper frame 4, in which there is an annular groove 14 on the inside for installing the end part of the spring 9.

The racks 6 of the lower frame 5 have upwardly extending ends 15, which are a continuation of these racks and are in contact with the racks 6 of the upper frame 4, while the upwardly extending ends 15 are able to move vertically relative to the racks 6 of the upper frame 4 and the side walls of the housing 1.

As can be seen from Fig.6, the racks of the lower frame 5 are installed in the vertical guides 16 located on the inner surface of the walls of the housing 1, and the edges of the racks 6 of the lower frame 5 are rounded, and the vertical rails 16 located on the inner surfaces of the walls of the housing 1 have the form vertical intersecting planes.

The side surface of the housing can be made in the form of a surface of rotation. In embodiments of the invention, the side surface may be multifaceted or multifaceted with rounded ribs.

The proposed valve operates as follows.

When the valve is closed, the space of the cavity of the housing 1 communicates through the nozzle 10 with the atmosphere, due to which atmospheric pressure is maintained in it. Under the action of the spring 9, the upper frame 4 is in its highest position, and the lower frame 5 is in its lowest position. The crossbar 7 of the upper frame 4 and the crossbar 7 of the lower frame 5 compress the elastic cuff 3 so that the lumen inside the cuff 3 is completely blocked and the possibility of liquid passing through the valve is excluded. The elastic ring elements 2 attached to the body are in this case in a stretched state and take a conical shape. In this position, the disks 8 of both frames 4 and 5 are as far apart as possible.

To translate the valve into an open position in the space of the cavity of the housing 1 by suction of air through the nozzle 10 create and maintain a relative vacuum (approximately 0.3 atm.). In this case, under the action of the pressure difference outside and inside the housing 1, the disks 8 of both frames 4 and 5 are brought together, the spring 9 is compressed, the upper frame 4 is moved to its lowest position, and the lower frame 5 is moved to its highest position. The walls of the elastic cuff 2 are straightened and the possibility of fluid flowing through the valve. At the same time, tensile stresses in the elastic ring elements 2 are weakened and they take a flat shape.

We note some positive properties of the proposed technical solution.

Located in the central parts of the disk 8 of the upper frame 4 and the crossbar 7 of the lower frame 5, the vertical protrusions 11 and 12 prevent the longitudinal bending of the spring 9, which increases the reliability of the clamping mechanism of the elastic cuff 3. The same purpose is the placement of the end of the spring 9 in the annular groove 14 made in an elongated vertical protrusion 12 of the disk 8 of the upper frame 4, because the upper end of the spring 9 is securely fixed from horizontal displacements relative to the hard disk 8 of the upper frame 4.

In the process of moving the valve from the closed position to the open and vice versa, the presence of vertical guides 16 on the inner surface of the side walls of the housing 1 prevents jamming of the moving frames 4 and 5 in the housing. This positive effect is facilitated by the presence of the protruding ends 15 of the uprights 6 of the lower frame 5 in contact with uprights 6 of the upper frame 4.

The execution of the side walls of the housing 1 in the form of surfaces of revolution simplifies its manufacture.

In accordance with this description, a prototype valve was manufactured, the testing of which in laboratory conditions showed good results. Currently preparing a batch of valves for testing in existing transport.

Claims (7)

1. Valve for vacuum sewer systems, including a hollow body, having expanded upper and lower parts, outside the side walls of the body there is a fitting for connecting the valve to the air duct, and elastic ring elements are attached to the edges of the side walls of the body from the top and bottom by outer edges, which can take a flat or conical shape, in the cavity of the body is an elastic cuff of cylindrical shape, the ends of which are attached to the edges of two holes made in the side walls of the body, the valve It is equipped with a clamping mechanism for an elastic cuff, consisting of an upper and lower frame, perpendicular to the axis of the elastic cuff, each of the frames consists of two vertical struts and a horizontal crossbar attached to the struts on one side and a horizontal disk on the other side, while the edges of the disks are fastened with the inner edges of the elastic ring elements, the racks of the upper frame are paired with the racks of the lower frame and connected to the side walls of the housing so that the racks of the frames have the possibility of longitudinal moving relative to each other and vertical moving relative to the walls of the case, each of the frames covers an elastic cuff and contacts the cuff with its crossbar, in addition, a spring is installed between the upper frame disk and the lower frame crossbar, vertical guides are provided on the inner surfaces of the side walls of the case, in which there are the outer edges of the racks of the lower frame, and these vertical guides are formed by intersecting planes, and the edges of the racks of the lower frame located in them olneny rounded. 2. The valve according to claim 1, characterized in that in the middle parts of the disk of the upper frame and the crossbar of the lower frame on the spring side there are elongated vertical protrusions that are located inside the spring and are interconnected with the possibility of vertical movement relative to each other and vertical movement relative to the spring . 3. The valve according to any one of claims 1 or 2, characterized in that in the central part of the disk of the upper frame there is an outer protrusion in which an annular groove is made on the inside of the housing for installation of the end part of the spring. 4. The valve according to any one of claims 1 or 2, characterized in that the racks of the lower frame have protruding ends that are extensions of these racks and are in contact with the racks of the upper frame, while the above protruding ends have the ability to move vertically relative to the racks of the upper frame and side walls of the housing. 5. The valve according to any one of claims 1 or 2, characterized in that the side surface of the housing is a surface of revolution. 6. The valve according to any one of claims 1 or 2, characterized in that the side surface of the housing is a multifaceted surface. 7. The valve according to claim 6, characterized in that the side surface of the housing is a multifaceted surface with rounded ribs.