DE564158C - Fluid meter - Google Patents

Description

Fluid Meters The invention relates to fluid meters with two alternately filling and emptying measuring vessels, in which the reversal of the liquid is only possible when the full measuring vessel is filled The delivery pressure of the pump acts on a moving wall. This movable wall can with automatic liquid meters z. B. the control slide via a tilting mechanism shifting pressure pistons or, in the case of knives reversed by hand, a changeover hand-preventing, connected to a locking device for the switching element Be membrane. In such measuring devices it is already known for the purpose of blocking the reversal up to the completed emptying of the respective outflowing measuring vessel the delivery pressure of the pump acting on the moving wall is thereby created to prevent a line discharging the measuring fluid from being open for so long is held as the measuring vessel has not yet been emptied. The invention aims a simplification of such locking devices. It is characterized in the claims and will be used in the following with reference to the drawing showing several exemplary embodiments explained in more detail, which is known per se in addition to the description of the inventive concept Represent facilities.

Fig. I shows the design of the invention for automatically acting Liquid distributor. Fig. 2 shows a complete automatic liquid distributor with all auxiliary devices.

Fig. 3 shows the design of the invention for non-automatically acting Liquid distributor. Fig. 4. shows a complete non-automatic liquid distributor with all auxiliary devices.

Referring to Fig. I, it can be seen that the liquid distributor has two measuring vessels i and 2, and that each has a float on the upper part 3 has, on which a valve q. is attached, which is the upper opening of the The measuring vessel can close as soon as the float is lifted through the liquid will, d. H. as soon as the vessel is full. The two rooms in which the swimmers 3 are movable, are connected to each other by a line 5, which to Air compensation is determined and has a valve 6 for the admission of the outside air in the event that there should be a vacuum in the line 5. The lower Part of each measuring vessel opens into a cylindrical space 7 in which a Piston 8 is movable, so that this piston on both sides of the in the Measuring vessels is exposed to prevailing pressures.

The piston adjusts the control slide io via a tilting mechanism 9, which through its movements ensures the alternating emptying and filling of one and the other measuring vessel. The liquid delivered through the line 13 enters one or the other measuring vessel, depending on how the control slide io is in the position shown for filling the vessel i or in a left position for filling the vessel 2. One or the other measuring vessel is emptied through the pipe 14. For example, the liquid can be supplied by a pump 12, as in: ebb. 2 shown. On the pressure line 13 of such a pump, a branch line 17 is placed, which is closed by a valve 18 which is under the influence of a compression spring ig, which is chosen so that for a predetermined fluid pressure in the line 13 this valve i8 a connection between the tubes 13 and 17 manufactures. The line 17 preferably opens into the suction line of the liquid pump as in Fig. Z, but can also lead to another point which is located in front of the pump.

According to Fig. 2, the pump 12 is for the liquid with a pump 15 coupled for compressed air, so that during operation of the pump 12 by means of a handle at the same time the air pump 15 is put into operation and compressed air into a line 16 pushes, which leads to the air tube 5. On line 16 is a check valve 2o and an overpressure valve 12i provided. If the line 17 is in the suction line ix allowed to flow out of the pump, it is advantageous to relieve the valve 18, to make it insensitive to pressure fluctuations in the suction line of the pump. For this purpose, as can be seen, the valve is arranged in a chamber which on the one hand by the valve 18 and its seat and on the other hand by an elastic Diaphragm 22 or the like is formed, the valve spindle with the diaphragm is attached. This chamber is connected to the suction line ii through the pipe 17 set so that the negative pressure created in the suction line ix by the pump "i2 on the inner surface of the valve 18 and on the inner surface of the diaphragm 22 expresses. The other side of the membrane is exposed to the atmospheric pressure and through a compression spring 1g loaded, which once and for all on the specified below Amount is set and the valve 18 presses on its seat, so that the immediate Connection between lines 13 and 17 is interrupted.

The mode of operation of this apparatus is as follows in the drawing is the measuring vessel 2 during emptying and the measuring vessel i during filling shown. As soon as the liquid in the measuring vessel i has reached the float 3, the same is lifted so that the valve 4 closes the opening and the passage the liquid to the air line 5 is blocked. Is the measuring vessel 2 at this point not yet completely empty and the pump 12 and thus also the pump 15 continue to be driven, the liquid is conveyed from the former and compressed air from the latter. This compressed air presses on the liquid surface in the measuring vessel 2 and accelerates thus its emptying. In addition, this creates compressed air on the right side of the Piston 8 has a counterpressure which supports the tilting clamping mechanism g and which is greater than the fluid pressure acting on the left side of this piston, causing the Piston 8 is prevented from moving to the right and the spool io to adjust. The pump 12 acts after the measuring vessel has been completely filled i Pumped excess of the liquid due to the increasing pressure on the valve 18 a, which opens, and flows via the line 17 to the suction line ii back, whereby the pump 12 is short-circuited. Requirement for opening of the valve 18 is that the spring ig of the valve is adjusted so that it is under a load that is less than the additional pressure of the compressed air or smaller than the sum of the additional pressure and that for adjusting the movable Wall 8 required pressure. However, if the measuring vessel 2 is completely empty and has been put in contact with the outside air by means of the line 14, the listener hears Back pressure of the compressed air on the right side of the piston 8, whereby the on the left side of the latter prevailing fluid pressure reversing the piston can cause by overcoming the Kippspannwerkesg. The control slide: [o moves then to the left, and the emptying of the vessel i and the filling of the vessel 2 can start again.

To control the air pressure, which is necessary for the tightness of the apparatus would be harmful to prevent, said safety valve 21 is used on the line 16, which opens at a pressure slightly greater than that to to lift the valve 18 from its seat.

The invention can be applied to non-automatic apparatus as well be used in which the control slide z. B. is a four-way valve, which is rotated by hand. Such training is shown in Figures 3 and 4.

Each of the two devices contains two measuring vessels 1 and 2 with floats 3 and valve 4, the air exchange line 5, the ventilation valve 6, the pressure line 13, the feed pump i2, the discharge line 14 for the liquid to be supplied and a four-way valve 23, which serves as a control part and alternately. the one and the other measuring vessel either with the line i3 or with the line 14 contacts.

From Fig.3 it can be seen that a line 17 is branched off from the line 13, which, as shown in Fig. 2, can open into the suction line ii of the feed pump. The line 17 contains a valve 18 which, as shown in Figure 4, can be relieved when the line 17 opens into the suction line ri of the feed pump. The line 16, which connects the air pump 15 (Fig. 4) with the air exchange line 5, contains the check valve 2o and a pressure relief valve? I. The two apparatuses according to Figs. 3 and 4 contain a four-way valve 23, which is to be locked in its position until one of the measuring vessels is completely full and the other completely empty. For this purpose, the locking and unlocking of the cock is placed under the influence of the pressure difference that prevails between the two measuring vessels, in the following way: With reference to FIG attached, which has two notches 25 and 26; Furthermore, an armature 27 is provided which swings about a fixed axis 28 and has two lugs 29, 3o. This anchor is arranged such that in one of the outermost layers of the valve, for. B. for the one shown in Fig. 3, the left nose 29 is in engagement with the notch 26, while the nose 3o of the armature engages in the second notch 25 for the other outermost position. This anchor is pushed forward in one sense and in the other by the intermediary of the push rod 31, which is hinged on the one hand to the armature 27 and on the other hand at 32 to the tilting clamping mechanism 9. The Kippspann-, Verk is stretched as in the previous example by the auxiliary piston 8, both sides of which are subjected to the respective pressures of the measuring vessels.

For each extreme position of the piston 8, e.g. B. for the left, as shown, which corresponds to the filling of the measuring vessel i, the anchor -, 7 locks the tap 23 in the corresponding position in which the line 13 is connected to the measuring vessel i, while the line 14 the measuring vessel 2 emptied. As soon as the pressure acting on the left side of the piston outweighs that on the other side of the piston, ie the point in time when the measuring vessel 2 is completely empty and the measuring vessel i is completely full, the piston 8 moves to the rightmost position and adjusted via the tilting mechanism 9 and through the intermediary of the push rod 31 also the armature 27 such that the nose 29 emerges from the notch 26, whereby the cock is unlocked so that it can be turned by hand. The nose 3o comes into contact with the circular disk at the same time and rides on it until the cock turned 90 ° to the right brings the notch 25 into engagement with the nose 30 of the armature and is locked in its new position, in which the measuring vessel i with the line 14 and the measuring vessel 2 is connected to the line 13. With reference to the embodiment according to Fig. 4, the valve 18 is relieved as in Fig. 2. The locking part is not adjusted by an auxiliary piston 8, but by an airtight, elastic membrane 33 or some other movable `` Fand ''. One side of the membrane is under the pressure of the liquid in the pressure line 13 of the pump and the other side is under the pressure of the compressed air conveyed by the pump 15. A rod 35 is attached to the spring-loaded diaphragm 33 and is connected at 36 to a pivot lever 39 which can pivot about a fixed axis 38. At its other end, this lever carries a bolt 40 which can collapse into one or the other of the notches 25, 26.

The operation of this embodiment is as follows: Once the pressure on the side of the liquid pressure line becomes significantly greater than that Pressure on the side of the compressed air, the membrane 33 is compressed, namely against the action of the compression spring 34, which is tensioned accordingly, so that they pivoted the lever 39 through the intermediary of the rod 35, whereby the bolt 4o is pushed out of the relevant notch, so that the tap 23 by hand can rotate in the opposite position. Is the rooster in this latter position arrived, the overpressure in the previously filled measuring vessel stops, and the , Membrane 33 enters its normal position, so that the bolt 40 again with a Notch, namely the other, can come into engagement, causing the tap in its is locked new position in which the filling of the other vessel is going on.

From the embodiments described it can be seen that just like the apparatus, whether automatically or manually controlled, the movement of the Reversing member or the control slide only takes place when the measuring vessels each are completely empty.

Claims (3)

PATENT CLAIMS: i. Liquid meter with two filling alternately and emptying measuring vessels, of which at least the measuring vessel being emptied is in connection with a source of compressed air supplying an additional pressure and at which the switchover the flow of liquid from a measuring vessel on the other is only possible when the liquid pressure in a filled measuring vessel on a movable wall that controls the reversing device for the meters or which itself forms the reversing device, comes into full effect, and in which the creation of full pressure by draining the liquid for so long what is prevented is how the emptying of the respective outflowing measuring vessel does not end is, characterized in that the movable wall (8) on both sides below the same additional pressure is at least as long as the filling of one vessel has not yet ended, and that the shut-off valve (18) for the discharge (17) under a load (compression spring 19) is less than the additional pressure or smaller than the sum of the additional pressure and that for adjusting the movable Wall (8 or 33) required pressure. 2. Liquid meter according to claim 1, characterized characterized in that the discharge line (17) into the suction line (11) of the liquid pump (12) opens. 3. Liquid meter according to claim 2, characterized in that the valve (18) with a deformable part, e.g. B. a membrane (22), such is connected that the opposite effects of the negative pressure of the suction line (11) on the diaphragm and on the valve.