RU2609376C1 - Conjugation structure - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: conjugation structure consists of the supply 1 and the discharge 2 channels, between which the bottom gallery 3 is provided, it is divided into two unequal parts, with the separating vertical transverse wall 6. The bottom gallery 3 is provided with installed vertical water duct 9 connected with the outlet pipe 8. The vertical duct 9 is shut by a shield in the form of a tray 7 rotatable in the direction of the supply channel 1. The lower end of the tray is secured to the upper end of the vertical transverse wall by the hinge 12, and the upper end of the tray is conjugated through opening of the gap with the end face of the supply channel 1 between the limiting stops 13 and 14 with the possibility of vertical movement relative to the supply channel. The upper end of the tray 7 is connected with the sensing element in the form of the spring 15 with the adjusting screw 16. The spring 15 is placed in the cavity of the housing 17, that protects it from damage and fouling. The sensing element in the form of the spring 15 supports the shield in the form of the tray 7 while moving it between its limiting stops 13 and 14. As a result, the limiting water level in the supply channel 1 is maintained, and excess water poured is discharged through the tray 7 into the second part of the bottom gallery 3.

EFFECT: enhanced control accuracy and operational reliability of the conjugation structure in conditions of variable water level in the supply channel.

3 cl, 2 dwg

Description

The invention relates to hydraulic engineering, and in particular to structures for connecting turbulent flows in canals.

Known structures for connecting the turbulent flow of the upper pool with the lower one, made in the form of a quick-flow tray, at the junction of which with the lower pool a shield is pivotally attached to the quick-flow tray with a float, and also a device is known when the supply channel is connected at an angle to the discharge channel , and has on its approach a section of high-speed flow (Copyright certificates SU No. 537162, Ε02В 8/00 from 11/30/1976 and No. 453469, Ε02В 9/00 from 12/15/1974).

Common drawbacks of such structures is that the impact of flows is accompanied by faulty and wave phenomena that worsen the working conditions of the structure and lead to their destruction, as well as the reliability of the shield is unreliable due to its non-rigid attachment to the float. In addition, it is not possible to divert the maximum (calculated) flow rate in the inlet channel in the automatic control mode of the opening value of the outlet of the inlet channel.

Also known are the nodes of the interfacing of the spillways of hydraulic structures (Author's certificates SU No. 8444669, Ε02B 9/06 of 07/07/1981, No. 950853, E02B 9/06 of 08/15/1982, No. 1168658, Ε02B 9/06 of 07/23/1985).

However, since they also have the connection of the flows of the supply pipelines at an acute angle, the collision of two flows occurs, which is accompanied by faulty and wave currents that worsen the working conditions of the structure. In addition, there is no possibility in the automatic mode to regulate the amount of discharge of the maximum flow rate in the inlet conduit.

It is also known mating structure, including the outlet channel and the inlet channels, one of which is located in plan at an angle to the outlet channel and connected to it by a section of quick-flow and a bottom gallery located under the dividing shelf, conjugated to the bottom of the other inlet channel and installed parallel to the bottom of the outlet channel moreover, it is equipped with a guide shield pivotally attached to the lower surface of the dividing shelf in its end part, and a transverse threshold installed at the bottom of the outlet channel the outlet of the bottom gallery and made with the upper face inclined towards the bottom of the gallery, while the side walls of the outlet channel are made with protrusions located under the guide shield with an inclination towards the threshold, and the guide shield is made of two articulated interconnected links, the upper of which has a length greater than the lower link, and pivotally attached by the upper edge to the dividing shelf with the possibility of interaction with the side edges with protrusions on the walls of the outlet channel, and the lower short the link is pivotally connected by the upper edge to the lower surface of the upper link in its end part with the possibility of interaction of the lower edge with the threshold at the bottom of the outlet channel (Copyright certificate SU No. 1359406, Ε02В 13/00 of 12/15/1987).

Since the inclined shield with its upper end is attached to the dividing shelf from the bottom, and its lower end is located cantilevered to the bottom of the outlet channel, this leads to its vibration in the flow, causing unrest when the flows under the shelf collide. The device also, with a further increase in the flow rate in the inlet channel, and therefore its filling (layer), presses on the shield under its weight and covers the outlet, lays on the transverse protrusions on the walls of the outlet channel and thereby creates a backwater in one of the inlet channels. Due to the installation of the shield in this way, the outlet for connecting the two flows reduces the collision of the two flows in its mass, which may be accompanied by a malfunction of the flow in the outlet channel, i.e. operational reliability decreases, while the retaining water horizon in the lower supply channel, covered by a movable shield in height due to the high pressure from above by the flow (weight) of water from the driving channel, therefore, the flow rate in it cannot ensure the discharge of the maximum flow rate (calculated), which causes it to overflow in the high-speed flow of water directly above the shield and contributes to the destruction of the inlet part of the outlet channel.

At the same time, an increase in pressure in the upper supply channel leads to pressure overloads on the shield from above, as a result of which the device’s operation will be limited only in the small opening range of the shield, since there will be a lot of pressure on the water shield from above, as a result, water will back up in the lower supply channel due to the possibility of the lack of discharge of an excess layer of water and its maximum flow rate in the upper driving channel.

Thus, there is a relationship between the costs in the supply channels between each other and the discharge channel, respectively, and the water pressure on the shield - all these connections in known structures affect the cost of the structure as a whole.

The problem to which the invention is directed is to increase the reliability of operation by reducing backwater in the inlet channel and reducing the flow failure in the outlet channel.

The specified technical result is achieved by the fact that in the mating structure containing the inlet and outlet channels and the bottom gallery located between them, closed with a shield on top, the bottom gallery is equipped with a discharge pipe located below the gallery bottom and is made with a vertical water conduit and a vertical transverse wall dividing the bottom gallery into two unequal parts, the shield is made in the form of a tray with the possibility of rotation towards the supply channel, while the lower end of the tray is pivotally attached to the upper end of the vertical pop of the transverse wall, and the upper end of the tray is interfaced through the opening of the lumen with the end of the supply channel, on which the limit stops are located, while the upper end of the tray with the spring position mechanism is fixed in the housing with the possibility of its movement when changing the position of the tray between the stops placed after the outlet opening of the supply channel, and the upper end of the tray, paired with a position mechanism, is placed with the possibility of vertical movement relative to the feed channel.

In addition, the spring position mechanism with the adjusting screw is placed in the housing, which is rigidly fixed to the gallery wall from the side of the supply channel.

In addition, the end face of the outlet channel is equipped with a directional inclined wall oriented towards the bottom of the gallery.

In FIG. 1 shows a mating structure, a longitudinal section; in FIG. 2 is a section Α-A in FIG. one.

The mating structure consists of a supply channel 1 and a discharge channel 2, interconnected by a bottom gallery 3, divided into two unequal parts 4 and 5 by a separating vertical transverse wall 6. The first part 4 of the bottom gallery 3 is closed from above with a shield in the form of a tray 7 with a discharge pipe 8 s a vertical water conduit 9. Behind the separating vertical transverse wall 6, the second part 5 of the bottom gallery 3 is connected to the outlet channel 2, the inlet end of which is provided with a directional inclined wall 10 oriented toward the bottom 11 of the gallery 3. The outlet I located below the bottom 11 galleries 3 pipe 8 for depressurised mode. A shield in the form of a tray 7 with the lower end of the hinge 12 is attached to the upper end of the vertical transverse wall 6, and the other end is connected with the end through the opening of the lumen with the end of the inlet channel 1 between the limit stops 13 and 14. The upper end of the tray 7 is connected to the sensor in the form of a spring 15 with an adjusting screw 16. A spring 15 and an adjusting screw 16 are placed in the housing 17, which is rigidly fixed to the wall of the bottom gallery 3 from the side of the inlet channel 1. The spring 15, attached at one end to the shield in the form of a tray 7, has the possibility free movement of the stroke of the tray 7 between the limit stops 13 and 14 of the tray 7, the lower end of which is hinged by 12 to the upper end of the vertical transverse wall 6. In this case, the spring 15 is attached and adjusted with the adjusting screw 16 to the tray 7 at a predetermined distance depending on the limit the water level in the inlet channel 1 with the aim of lowering it to the limit stop 13 when excess water is discharged into the vertical conduit 9, then into the outlet pipe 8, to the maximum steady level in the inlet channel 1, i.e. the shield in the form of a tray 7 occupies a position in which excess water is discharged into the second part 5 of the bottom gallery 3, where the flow is extinguished by falling onto the directional inclined wall 10. The spring 15 not only acts as a retaining structural element, but can change the mechanism of change the position of the tray 7 in the form of an adjusting adjusting screw 16, rigidly fixed to the housing cover 17.

The mating structure operates as follows.

From the inlet channel 1 with a flow rate less than or equal to the limiting flow, the water flows into the dividing bottom gallery 3, respectively, under the bottom of the shield made in the form of a tray 7, changes its movement and enters the vertical conduit 9, then into the outlet pipe 8 and to the consumer. The upper end of the tray 7 is pressed against the stop 14 of the inlet channel 1 through the opening of the gap between them due to the adjusted force of the spring 15, i.e. under the action of an adjustable screw 16 located in the housing 17. Moreover, this incoming water flow into the vertical conduit 9, coupled to the discharge pipe 8, is separated by a vertical transverse wall 6 from the second part 5 of the bottom gallery 3 due to the position of the discharge pipe 8 below the bottom 11 of the gallery 3 .

When the water flow in the inlet channel 1 exceeds the limit value (calculated filling), the excess water is directed from above onto a shield made in the form of a tray 7, it is filled, and therefore the weight of the water in the tray 7. Under the gravity of the incoming water to the shield in the form of a tray 7, it partially rotates around the hinge 12, reducing the output cross section of the discharged water flow into a vertical water conduit 9 with a discharge pipe 8 and separated by a vertical transverse wall 6 located on the bottom 11 of the gallery 3. Having reached, limit of the thrust stop 13 (lower) at the end of the inlet channel 1, lowering the tray 7 down will be completed for the maximum discharge flow rate into the vertical conduit 9 with the outlet pipe 8. The separating vertical transverse wall 6 isolates the first part 4 from the second part 5 of the bottom gallery 3, parts 4 and 5 are made of two unequal parts between each other. Next, the flow from the tray 7 merges into the second part 5 of the gallery 3, the flow meets the resistance of the directional inclined wall 10, is extinguished and, changing this time the direction of movement, enters the outlet channel 2, for example, for the next accumulation of the daily regulation basin (BSR) of the reservoir by the water or directly to the consumer. Thus, the incoming water stream from the inlet channel 1 is divided into two streams, i.e. one of its calculated part enters the vertical conduit 9 with a discharge pipe 8, and the other excess part of the flow through the tray 7 merges into the second part 5 of the bottom gallery 3. Due to the circuit diagram of the regulatory body, which provides a sensing element in the form of a spring 15 placed in the housing 17, with an adjusting screw 16 in the housing 17, which is rigidly fixed to the wall of the bottom gallery 3 from the side of the inlet channel 1. The excess water will be drained without splashing into the second part 5 of the bottom gallery 3, while the shield in the form of a tray 7 ra is parallel to the axis of the inlet channel 1, which ensures the removal of excess water flow to the maximum level in the inlet channel 1. The necessary delay of the tray 7 on the stop 13 (lower) during the discharge of excess water from the inlet channel 1, exceeding the maximum level in it, It is automatically adjusted until the flow rate decreases in the supply channel 1 due to the snow of the presence of sensitive elements of the device. The balance of systems is again upset. As a result, the shield in the form of a tray 7 is again rotated around the hinge 12, increasing the cross-sectional opening of the vertical water conduit 9 with the outlet pipe 8, which is supported by lifting the tray 9 upward, towards the bounding ledge 14 (upper) of the end of the tray 7 by the spring 15. The spring does not work the passage of suspended and bottom sediments will affect the presence of the enclosing body 17, rigidly attached to the wall of the bottom gallery 3.

Due to the connection of the spring 15 with the end face of the movable shield in the form of a tray 7, a damping effect on the tray 7 is provided, and suspended sediments are washed away from it into the second part 5 of the bottom gallery 3, which increases the reliability of regulation of the device.

Thus, the constancy of the change in the weight of water flowing through the shield in the form of a tray 7 and its altitude when in contact with the limit stops 13 and 14 is obvious from the circuit diagram of the control board in the form of a tray with a spring 15, will ensure the reliability of the mating structure as a whole. Changing the tension of the spring associated with the shield in the form of a tray can be carried out using the adjusting screw, which leads to a change in the extreme positions of the shield in the form of a tray and its contact with the limit stops. Each part of the flow entering the bottom gallery is isolated with respect to hydraulic disturbances of each of the parts in the trench, separated from each other by a vertical transverse wall, and therefore moves in a compact stream without gushing, and the water flow is regulated automatically by a shield made in the form of a tray. It should be borne in mind that the stability of transients of the hydraulic regime that arise during the operation of the structure is ensured by the rational layout and the technically competent constructive solution of the mating structure. This interconnection and interdependence of the main elements of the structure ensures operational reliability and accuracy of the maximum flow rate in the inlet channel when the water level changes in it and the optimal throughput in conditions of accumulation of excess water in the BSR or in reservoirs for the consumer.

The advantage compared to the prototype is to increase the accuracy of regulation, the stability of operational reliability due to the lack of influence of sediment on structural elements. Changing the installation of the sensor is performed by changing the tension of the spring by unscrewing the screw. This allows you to carry out regulation in automatic mode, having a simple system of nodes, and flushing takes place under the pressure of water.

Claims (3)

1. The mating structure containing the inlet and outlet channels and the bottom gallery located between them, closed by a shield on top, characterized in that the bottom gallery is equipped with a discharge pipe located below the bottom of the gallery and is made with a vertical water conduit and a vertical transverse wall that divides the bottom gallery into two unequal parts, the shield is made in the form of a tray with the possibility of rotation towards the supply channel, while the lower end of the tray is pivotally attached to the upper end of the vertical transverse wall, and the upper end the failure is interfaced through the opening of the lumen with the end of the supply channel on which the stops are located, while the upper end of the tray with the spring position mechanism is fixed in the housing with the ability to move it when changing the position of the tray between the stops placed after the outlet of the supply channel, and the upper end of the tray, paired with the position mechanism, placed with the possibility of vertical movement of the relative supply channel. 2. The mating structure according to claim 1, characterized in that the spring position mechanism with the adjusting screw is placed in the housing, which is rigidly fixed to the gallery wall from the side of the supply channel. 3. The mating structure according to claim 1, characterized in that the end face of the outlet channel is provided with a directional inclined wall oriented toward the bottom of the gallery.

Images