NL8901772A - LOCK WITH AUTOMATIC SLIDER. - Google Patents

Abstract

The invention concerns an under opening automatic sluice with a cylinder shaped gate (1) tilting around a horizontal axis which is positioned in the centre of the shaft (3). The size of the opening of the gate is controlled by one or more floating counterweight(s) (17) which is (are) positioned in (a) housing(s) (18) and which is (are) in open connection with the upper or lower water level. Because the centre of gravity of the gate (1) changes place horizontally with the gate movement, it is possible to maintain a preadjusted level. By adjustment of the bow-formed cylinder wall (2) with respect to shaft (3) it is possible to influence the operation characteristic of the gate.

Description

Lock just automatic slide.

The invention relates to a lock with an automatically operating cylindrical slide rotatable about a horizontal axis. The size of the slide opening is controlled by one or more floating counterweights that move the slide via a transmission mechanism. Each floating counterweight is located in a space that communicates either with the upper level or with the lower level. Because the center of gravity of the slider moves during the turning of the slider, a differentiated effect can be obtained with changing water in and out.

A sector-shaped slide is known from application EP-A-249558. This slider depends on a sufficient level difference to obtain the required vacuum for the control. Because the control openings have indirect contact with the outside water, they can easily become dirty.

The invention provides a reliable and simple slide with particularly favorable properties with regard to the water quantities to be processed. This is achieved by using a cylindrical slide which can be rotated about a horizontal axis. The slide opens at the bottom and is adjusted with the help of a floating counterweight. By adjusting the arcuate cyun of the wall relative to the axis of the slider, it is possible to influence the characteristic of the slider by means of the resultant hydrostatic forces.

The invention is described with reference to the drawings, in which the following figures:

Fig. 1 is a sectional view of the slide in the longitudinal direction of the watercourse, seen according to the letters B-B in figure 2.

Fig. 2 shows a cross-section of the slide according to the letters A-A in figure 1.

Fig. 3 shows the construction in case the control depends on the upper level.

Fig. 4 shows the construction of the adjustable cylinder wall.

The slide <1> consists of a curved plate (2) which is in the form of a part of a cylinder, called a cylindrical wall (2), which is attached to the rotatable horizontal axis (3) with bearings (4). The axis of the cylindrical wall (2) lies in or near the rotatable shaft <3>. The slide (1) can be provided with a cladding (5). This plating is provided with openings (6) in order to have an open connection between the space in the slide <1> with the lower level (7). The slide (1) has a diameter such that the slide is equal to or above the highest permissible or occurring upper level. (8) reaches. A threshold (10) is placed on the bottom of the watercourse (9) against which the bottom edge (11) of the slide (1) can strike. The watercourse at the location of the slide is bounded by two vertical walls (12), (13). A walkway (14) connects both walls. The slide (Dis laterally sealed with two plates (15) which connect the shaft (3) to the cylindrical wall (2). Sealing strips (16) form the seal between the vertical walls (12), (13) and the slide (1).

The floating counterweight (17) is suspended in a housing (18) with inspection hatch (19). The shaft (3) extends through the wall of the housing (18) and is provided with a disc (20). This disc (20) is driven by a cable (21) through disc (22). Disc (22) is fixedly mounted on shaft (23) which is mounted in bearings (24). A disc (25) is mounted on shaft (23) which can be coupled to a disc (26) fixedly mounted on the shaft (23). The floating counterweight (17) is connected to disc (25) with a cable (27). The opening (28) connects the housing (18) to the lower level (7). The transmission between disc (22) and (20) can also be done by means of a chain or timing belt.

Due to the asymmetrical shape of the slider (1), the center of gravity of the slider (1) will lie somewhere between the cylindrical wall (2) and the shaft (3), so the weight of the slider (1) will make it close, Deresultante the hydrostatic forces will pass through the cylindrical shape of the wall (2) through the shaft (3) of the slide (1) and thereby exert no torque on the slide (1). The floating counterweight (17) is connected by the discs (25), (26), (22) and (20) and via shaft (23) and cables (27) and (21) to the shaft (3) of the slide (1 ) connected. By adjusting the coupling between disc (25) and (26), the floating counterweight (17) can be lifted out of the water until the slide (1) is in balance. When the lower level (7) drops, the floating counterweight (17) will open the slide (1) and water will flow from the upper to the lower. When opening the slider (1), the center of gravity of the slider (1) will move horizontally towards the shaft (3), reducing the imbalance of the slider and further opening the floating counterweight (17) of the slider (1). In this way, the slider (1) will progressively open but thus adapt to a new equilibrium situation at a constant but slight drop in level. The lower level (7) is adjusted using the coupling between disc (25) and (26). The adjustment can be done, for example, with a (not drawn) worm and worm gear transmission. The sliding adjustment depends on the diameter ratio of the cable pulleys (20), (22) and (25).

In Fig. 3 a construction is shown in case the upper level (6) determines the control of the opening of the slide (1). The floating counterweight (17) is connected to a push rod (35) to which two cable connectors (36) are attached.

A disc (37) is adjustably connected to disc (26) on shaft (23). A cable (38) is wound between the cable connectors (36) and wrapped around disc (37) for non-slip connection. The flanges (39) serve to guide the push rod (35). The floating counterweight (17) is pressed into the water to such an extent that the buoyancy compensates for the imbalance of the slide (1). When the upper level (8) rises, the floating counterweight (17) will open the slide (1). The cable construction described here can also be carried out with a toothed rack or timing belts.

Fig. 4 shows a variant. This makes it possible to change the characteristics of the lock during operation. The wall (2) is hinged to the plating (5) with hinge (29). At (30) is an adjustment mechanism with hinge points (31) and (32). By displacing the axis of the cylinder to (33) the resultant of the hydrostatic forces (34iv§ie slider (1) will cooperate with the opening of the slider. This means that the upper level (8) also influences the operation. With a large water supply, the higher upper level (8) will open slider C1). This embodiment makes it possible that a virtually constant level difference between lower (7) upper level (8) can be maintained.

The simple design of the threshold (10) and slide (1) prevent accumulation of dirt and obstructions. It is not necessary to install grids, which reduces maintenance and increases reliability.

Claims (1)

41 Automatic lock valve according to claims 1, 2 and 3, characterized in that one or more floating counterweights are located in a space which is connected to the upper level. 5] Automatic slide valve according to claim 1, 2, 3 and 4, characterized in that the cylinder wall is less than a half cylinder and the center of gravity of the sliding construction lies between the cylinder wall and the axis of rotation.