DE3703254C2 - Mixing device for brine and fresh water - Google Patents

Description

The invention relates to a mixing device according to the Preamble of the first and third claims.

In a known mixing device of this type (DE 35 18 962 A1) opens an inlet line for brine and fresh water into a mixing chamber from which a drain line leads away. One of the end openings is located within the mixing chamber the inlet lines associated with a valve device as pivotable valve body trained actuator that in turn with a float arranged in the mixing chamber connected is. The specific total weight of the swimmer is to the specific weight of the Brine matched. As a result, the flow channels of the Valve device controlled so that the float certain adjustment path of the actuator the free Flow cross sections of the feed lines in the area of Change the end openings in opposite directions and the salt molecule concentration is kept constant. After for the pivoted Actuator an essentially horizontally projecting and the Actuator arm carrying a float is required builds this device is relatively large in the horizontal direction. In addition the horizontal installation position must be observed exactly because deviations from this directly affect the mixing ratio impact.

Another known mixing device (DE 35 15 727 A1) is directly to a salt container for softening devices of household appliances, especially dishwashing or Molded on washing machines. The one at the top Screw lid lockable salt container is in the upper area supplied with fresh water via a connecting piece. A  The waterway leads via a throttle section up into the Salt container in which on a floor with a Sieve device salt is stored. After the sieve arrangement follows a storage room for concentrated brine, one of which Inlet pipe opens freely into a mixing chamber from below. In this mixing chamber opens a further inlet line which a second throttle section directly to the fresh water is to be fed to the connecting piece. The parallel brine flowing into the mixing chamber and the fresh water mix in this mixing chamber and pass from there if necessary, a drain pipe leading upwards into one downstream ion exchanger via. In operation it has shown that the concentration of the brine is dependent on the Dwell time of the fresh water supplied in the stored salt. So the brine concentration depends on the layer thickness of the Salt in the salt container, from that flowing in in the time unit Amount of fresh water, by duration, during which none Brine was taken and also from the amount and duration of the Brine extraction.

The invention has for its object in a 3. Mixing device according to the preamble of claims 1 and 3, respectively Take measures by which a space-saving and variable installation is guaranteed.

This object is achieved according to the invention by Characteristic features of claims 1 and 3 respectively.

In one embodiment of a mixing device Invention is the actuator immediately in the direction of Buoyant forces of the assigned float moves, so that both Parts can be arranged axially. It is because of it no force redirection and therefore no swivel bearing required. The actuator can as a whole Float be formed. The vertical adjustability the actuator of the valve device also results in a largely smooth, easy-to-create structure. If the actuator has a linearly displaceable slide There are cross bores for each side feed pipe, the feed lines at least approximately perpendicular to  Adjustment direction of the slide are in Directional force components of the inflowing Avoid liquid on the slide. Will the Inlet lines directed towards each other from above and below in inserted the mixing chamber, then the actuator can if necessary integrated float, between the end openings of the Inlet lines are adjustable. With this setup can be designed as a ball, the actuator must be surrounded by a cage that serves as a guide. If the actuator is cylindrical or conical, it is on the other hand, it is advisable to provide a vertical guide rod, which guides the actuator in the vertical direction and Avoid canting. The compact summary of Actuator and floating body in an axis-aligned arrangement results a space-saving structure, with easy Position deviations from the target position on the mixing ratio practically not impact.

The invention is based on the sketches of Exemplary embodiments explained in more detail. It shows:

Fig. 1 a salt container with integrated mixing device in section,

Fig. 2 shows a mixing device with inlet lines ending in parallel horizontal walls and an actuator arranged therebetween with a float arranged separately therefrom

Fig. 3 shows a mixing device with the same arrangement of the inlet lines and floating body and actuator combined into a single component.

A salt container ( 1 ) has a filler neck ( 2 ) on its upper side, which is closed by means of a removable closure cover ( 3 ) and is used for filling a salt reservoir. The salt reservoir is deposited on an inclined bottom wall ( 4 ), from which a gap ( 5 ), optionally provided with a sieve arrangement, opens into a brine storage chamber ( 6 ) provided under the inclined bottom wall ( 4 ). Removed from the gap ( 5 ), a feed line ( 7 ) leads from the brine storage chamber ( 6 ) to a controllable actuator of a valve device designed as a slide ( 8 ). A further inlet line ( 9 ) leads to the slide ( 8 ) and opens into a connection pipe ( 12 ) leading to fresh water via a fresh water channel ( 10 ) running along the wall of the salt container and a throttle point ( 11 ). Another throttle section ( 13 ) leads from the connecting piece ( 12 ) into the upper region of the salt container ( 1 ). The slide ( 8 ) is vertically displaceably mounted in the wall parts of a mixing chamber ( 14 ) and has transverse bores ( 15 ) as flow channels of the valve device. The slide ( 8 ) serving as an actuator is assigned to both feed lines ( 7 and 9 ), the transverse bores ( 15 ) being provided in such an arrangement that the free flow cross sections of the feed lines change in opposite directions over the adjustment path of the slide ( 8 ). In the end positions of the usable adjustment path, the free flow cross sections of one supply line are thus alternately open and the other supply line largely closed. The feed lines ( 7 , 9 ) are brought at least approximately perpendicular to the direction of adjustment of the slide ( 8 ) to the slide, so that force components exerted by the flowing liquids cannot act in the direction of displacement of the slide ( 8 ). The feed lines are preferably guided parallel to one another and side by side from one side to the slide. In the mixing chamber ( 14 ) there is a floating body ( 18 ) which is attached directly to the upper end of the slide ( 8 ). The specific total weight of the float ( 18 ) with the slide ( 8 ) is equal to the setpoint of the specific weight of the brine required in the mixing chamber or its drain line ( 19 ) leading upwards, as it is used for the regeneration of the connected to the drain line, Ion exchanger, not shown, is required.

If fresh water is supplied via the connecting piece ( 12 ), then it flows on the one hand through the throttle section ( 13 ) directly into the salt container ( 1 ), from which it contains the brine, the specific weight of which is greater than that of the fresh water, through which concentrated brine filled brine storage chamber ( 6 ) and the associated supply line ( 7 ) presses. At the same time, fresh water is conveyed directly through the fresh water channel ( 10 ) to the feed line ( 9 ) via the throttle section ( 11 ). The relatively highly concentrated brine and the fresh water then flow through the associated transverse bores ( 15 ) into the mixing chamber, where they are mixed to a brine concentration as required for the ion exchanger. The float ( 18 ) automatically adjusts the position of the slide ( 8 ) depending on the brine concentration actually present in the mixing chamber for the automatic adjustment of the corresponding mixing ratio.

In softening plants, regeneration is generally carried out with a 10-12 percent saline brine. The target value of the specific weight is then around 1.1-1.12. The floating body ( 18 ) with the slide ( 8 ) has the same specific weight. Accordingly, if the specific weight of the brine mixed with fresh water in the mixing chamber ( 14 ) is higher than the specific weight of the floating body ( 18 ), then it rises and closes partially or completely depending on the concentration of the brine in the mixing chamber ( 14 ) The free cross-section of the flow channel from the feed line ( 7 ) for the highly concentrated brine from the brine storage chamber ( 6 ) by means of an adjustment of the slide ( 8 ) upwards via the slide ( 8 ) coupled to it. As a result, the associated transverse bore ( 15 ) moves partially or completely out of the overlap area with the free end opening of the inlet line ( 7 ). The float ( 18 ) with the slide ( 8 ) moves upwards. During this movement of the rectilinear and vertically displaceable slide ( 8 ), the flow channel cross section for fresh water is increased to a maximum value in which the end opening of the fresh water supply line ( 9 ) comes into full overlap with the associated transverse bore ( 15 ). As the supply of concentrated brine decreases, the amount of fresh water supplied is increased. This reduces the concentration of the brine in the mixing chamber ( 14 ). If the brine concentration is reduced below the target value determined by the specific total weight of the float body ( 18 ) with the slide ( 8 ), on the other hand, this arrangement drops downwards and results in increasing overlap of the end opening of the inlet line ( 7 ) with the associated transverse bore ( 15 ) free an enlarged inlet cross-section for concentrated brine, while the inlet cross-section from the fresh water inlet line ( 9 ) is reduced to the same extent via the associated transverse bore ( 15 ). In the mixing device formed by the mixing chamber ( 14 ) with the float ( 18 ) and the slide ( 8 ) in cooperation with the feed lines ( 7, 9 ), the salt molecule concentration is automatically set to a predetermined value. Accordingly, if there is a change in the brine concentration in the brine storage chamber ( 6 ) when a larger amount of brine is withdrawn, these fluctuations are automatically compensated for in the mixing device.

In addition, the back pressure is greater when the salt container ( 1 ) is largely filled with salt for the incoming fresh water than at a low salt level, so that the flow pressure at the inlet line ( 7 ) also decreases to a corresponding extent. The resulting reduced supply of concentrated brine into the mixing chamber ( 14 ) is also regulated. Furthermore, the concentration of the brine in the brine reservoir ( 6 ) also drops more quickly if the contact time of the fresh water supplied with the stored salt is so short that a completely saturated brine cannot form with a larger amount of brine withdrawn and a small amount of salt. The perpendicular to the displacement direction of the slide (8), feed lines (7, 9) cause no pointing in the direction of displacement of the slider (8) force component can act on the slide (8) by the inflowing liquid. This also does not affect the control characteristic of the float ( 18 ) with the slide ( 8 ), which is dependent on the specific weight. The slide ( 8 ) is mounted in horizontal walls ( 20 ) or 21 of the mixing device in corresponding bearing bores so as to be easily displaceable. The slide ( 8 ) slides directly in front of the end openings of the feed lines ( 7 , 9 ), which forms directly controllable valve sections and does not require an independent valve device to be installed.

Referring to FIGS. 2 and 3, the feed lines in end openings (22) and 23, which are disposed in opposing, horizontal walls 24 and 25 end. The end openings ( 22 , 23 ) are aligned in the vertical direction, the actuator ( 8 ) being arranged between the two end openings ( 22 , 23 ). According to FIG. 2, this actuator is formed by a shut-off body which is conical at the top and bottom and is guided vertically displaceably in the walls ( 20 , 21 ) via a vertical guide rod ( 26 ). The float ( 18 ) sits in the mixing chamber ( 14 ) at the upper end of the guide rod ( 26 ). If the brine concentration rises in the mixing chamber ( 14 ) in an arrangement according to FIG. 2, the float ( 18 ) pulls the actuator ( 8 ) upwards, as a result of which the inflow of concentrated brine is restricted. When the brine concentration drops, on the other hand, the actuator ( 8 ) sinks downward and releases the flow cross-section from the inlet line ( 7 ) more and more, while the lower end of the actuator ( 8 ) increasingly into the end opening ( 23 ) of the fresh water inlet line ( 9 ) dips and throttles their free flow cross section.

The actuator ( 8 ) can also be designed as a floating body according to FIG. 3, so that bearing guides in the walls ( 20 and 21 ) can be omitted. The actuator ( 8 ) is then preferably designed as a ball and held in the region of the end openings ( 22 , 23 ) by external boundaries. In addition, the actuator of the valve device can also be actuated by an external motor drive unit, which is controlled by a sensor that detects the brine concentration in the mixing chamber.

Claims (7)

1.Mixing device, each with an inlet line for brine and fresh water and with a mixing chamber and an outlet line leading therefrom, with two inlet lines associated with a controllable actuator valve device, which has flow channels in such an arrangement that the free path over the adjustment path of the actuator Change flow cross-sections of the supply lines in the opposite direction, as well as with a floating body arranged in the mixing chamber, which is connected to the actuator and whose specific total weight is adapted to the target value of the specific weight of the brine required in the discharge line, especially for salt containers of softening devices in household appliances, such as dishwashing or Washing machines, characterized in that the actuator has a slide ( 8 ) which is mounted such that it can be displaced vertically and in a straight line and has transverse bores ( 15 , 15 ) as flow channels for each inlet line ( 7 , 9 ) is that the supply lines ( 7 , 9 ) are at least approximately perpendicular to the direction of adjustment of the slide ( 8 ) to the slide ( 8 ) and that the slide ( 8 ) is connected directly to the float ( 18 ). 2. Mixing device according to claim 1, characterized in that the feed lines ( 7 , 9 ) parallel to each other and side by side to the slide ( 8 ). 3. Mixing device, each with an inlet line for brine and fresh water, as well as a mixing chamber and an outlet line leading therefrom, with two inlet lines associated with a controllable actuator valve device, the flow channels in such an arrangement that the free over the adjustment path of the actuator Change flow cross sections of the supply lines in the opposite direction, as well as with a floating body arranged in the mixing chamber, which is connected to the actuator and whose specific total weight is adapted to the setpoint of the specific weight of the brine required in the discharge line, especially for salt containers of softening devices in household appliances, such as dishwashing or Washing machines, characterized in that the actuator ( 8 ) is vertically adjustable and is connected directly to the floating body ( 18 ), that the feed lines ( 7 , 9 ) face each other n, horizontal walls ( 24 , 25 ) end and that the actuator ( 8 ) between the walls ( 24 , 25 ) or the end openings ( 22 , 23 ) of the inlet lines ( 7 , 9 ) is adjustable. 4. Mixing device according to claim 1 or one of the following, characterized in that the actuator ( 8 ) is simultaneously designed as a floating body. 5. Mixing device according to claim 3 or 4, characterized in that the actuator designed as a floating body ( 8 ) has a spherical shape. 6. Mixing device according to claim 3 or 4, characterized in that the actuator ( 8 ) is formed by a conical shaped shut-off body as above. 7. Mixing device according to claim 3 or one of the following, characterized in that the actuator ( 8 ) is slidably mounted by means of a vertical guide rod ( 26 ).