DE623567C - - Google Patents

Description

The invention relates to pumps for pumping liquids and relates to in particular a pump, in which by periodic pressure fluctuations of a Liquid in a continuously heated container, vapor and thereby liquid pushed through a check outlet valve and then cold liquid is sucked in via a check inlet valve.

Pumps of this type have the disadvantage that a considerably larger amount of liquid must be heated than to generate the necessary to carry out a stroke ■ 15 necessary steam is necessary because liquid is above the heat supply point is located, which, as is known, must be heated to a temperature corresponding to the boiling point before above the Liquid level, steam can be generated. The whole system is therefore under-working much higher temperature than is necessary for proper operation, which in turn results in a reliable and lasting effect the pump is in question.

The purpose of the invention is now to eliminate this disadvantage, namely by that the heated container is provided on the shorter leg of a U-shaped tube is and from a heated part with a relatively large heating surface and from an unheated part consists of unconstricted, parallel to each other Channels connected to the heated part, and that to the upper end of the unheated Part of a knee-shaped bent pipe reaching down to the level of the lower connecting channel is connected is, the lower end of which through a tube of narrow internal width to the upper end of the long leg is connected below the check outlet valve.

In the drawings, in FIGS. 1 to 5, schematic views of the subject matter of the invention are shown as an example in five embodiments. forms shown.

In the pump of Fig. 1, a condenser-forming non-return outlet valve c is provided on the longer leg α of a U-shaped bent tube and a container consisting of an unheated part & and a heated part f is provided on the shorter leg. At the upper end of the unheated part b of the container, a downwardly extending knee-shaped bent tube d is connected, the lower end of which is connected by a tube e of small internal width to the upper end of the long leg a ' below the check outlet valve c .

The unheated part b of the container is connected to the heated part / small volume at the top and bottom through unconstricted channels running parallel to one another. In the U-shaped bent tube opens an inlet connection g with a return valve h.

When the pump is completely filled with a liquid, e.g. B. water, has been filled to and the part / the container heat is supplied to its upper. The end of vapor is formed by which the liquid enters. the heated and unheated part of the container as well as in the pipe d downwards, whereby at the same time liquid is pressed through the pipe e smaller inside diameter, which escapes through the check outlet valve c. The pump continues to operate in this way until the liquid level in the various pipes has dropped to the level of the lower end of the knee-shaped bent pipe d. As soon as steam flows from the tube d into the tube e and this reaches the upper end of the long leg α , liquid is pressed from the latter to the unheated part b of the container, so that the latter and the tube d and the heated part f again with liquid to be filled. Fresh liquid flows in through the check inlet valve h so that the pump is again completely filled with liquid and the cycle described is repeated.

In the pump according to the invention, therefore, considerably less heat is required to carry out a complete stroke than in a case in which the heat would be supplied to the unheated part b. Accordingly, the temperature of the entire pump is lower, and since the pressure limits between which the pump operates depend on the temperature of the condenser and the pump, the lower the heat consumption to induce the pumping stroke, the range of possible temperature drop in the hydraulic The reverse is the greater, and consequently the possibility of the occurrence of a condition causing the pump to fail, namely the possibility that the remaining liquid is heated to such a temperature that its vapor pressure is above the inlet pressure, the smaller and the The greater the range between the highest and lowest pressures that allow the pump to work.

The pump is used to convey liquids that have absorbed gases, e.g. B. Ammonia-water solutions can cause the inlet valve to open with every stroke Pressure reduction can be brought about by sucking off the gas again.

The pump according to FIG. 2 is particularly suitable for pumping large amounts of liquid per stroke or for pumping against a considerable pressure. In this embodiment, too, there is a U-shaped bent tube a, b with a downwardly directed, knee-shaped bent tube d, a tube connecting the lower end of the tube d to the leg α with a smaller internal width and a heated part forming the evaporation container / Use. The latter is connected to the unheated part b , but the lower connection piece / between the parts / and b has an upwardly directed end, so that when the liquid flows upwards through the latter, an ejector effect is achieved which prevents the liquid from flowing into the lower end of the heated part / prevented as long as the liquid is in motion.

The operation of this pump is similar to that described above. Here, however, it is not the parts b and / both that are quickly filled with liquid from the long leg α , rather it is. prevents the liquid from flowing into the lower end of the heated part / through the ejector effect, but without influencing the vapor transmission from the unheated part & to leg 0. The effect of the heated part / is therefore delayed until the hydraulic reversal has ended and the inlet stroke, ie the renewed filling of the pump, has been initiated.

The delayed pump according to FIG. 3 is particularly suitable for forcing large quantities of liquid or for pumping against considerable pressure. The lower end of the heated part / is here connected by a pipe k to the lower end of the downwardly bent, knee-shaped pipe d instead of to the unheated part b .

The operation of this pump is similar to that described above in that the flow of the liquid into the heated part is delayed until the pressure is reduced enough to initiate the next intake stroke, because only steam is present in the lower connecting pipe h.

The inlet port m of the pump according to FIG. 4 opens instead of the U-shaped tube in an auxiliary container n, which is connected with its upper and lower ends to the long leg α of the U-shaped tube near the check outlet valve c . Into the upper end of the auxiliary

ters η protrudes into the depending end ο , which is expediently enlarged in diameter, of the tube e branching off from the lower end of the knee-shaped bent tube d extending downward from the unheated part b.

The extension ο of the tube e forms a delayed condenser, which allows an initial violent liquid oscillation and then prevents any flow of liquid down the tube e and thereby filling the heated part / until the whole pump is filled with liquid.

If pumps according to the invention for pumping oils, ζ. Β. Paraffin oil, it is advisable under no circumstances to heat the heated part f until it is completely dry, as this easily precipitates solid substances.

In the pump according to FIG. 5, the results achieved with the pump just described, namely rapid liquid oscillation and prevention of the premature backflow of the liquid through the pipe e , are achieved in a simple manner in that the auxiliary container η according to FIG. 4 is omitted and the tube e is connected to the highest point of the leg α . The upper end of the latter then forms a capacitor operating with delay, but the leg α at p is enlarged in cross section at a point slightly below the upper end in order to ensure effective condensation at this point. The liquid inlet port q is designed in the form of an injector, so that the liquid circulation in the U-shaped bent tube in a downward direction in the leg α is promoted, whereby every effort to suck liquid downward through the tube e and thus to cause an early generation of steam , is counteracted.

Claims (6)

Patent claims: i. Pump for pumping liquids, in which vapor is derived from a liquid in a permanently heated container due to periodic pressure fluctuations and liquid is thereby forced through a non-return outlet valve and then cold liquid is sucked in via a non-return inlet valve, characterized in that the heated container has a U-shaped tube is provided and consists of a heated part (/) with a relatively large heating surface and an unheated part (b) , which is connected to the heated part (/) by unconstricted, parallel channels, and that to the The upper end of the unheated part is connected to a knee-shaped bent pipe (rf) reaching down to the level of the lower connecting duct, the lower end of which is connected to the upper end of the long leg below the non-return outlet valve (c) by a pipe (e) of narrower width is. 2. Pump according to claim 1, characterized by a device controlled by the liquid oscillation Delay the fluid supply after the heated container (/) until the pressure dropped in the pump to a value below the pressure of the liquid source is. 3. Pump according to claim 2, characterized in that the protruding into the LJ-shaped tube end of the lower connecting channel between the heated (/) and the unheated part (b) of the container is designed as an ejector (j) . 4. Pump according to claim 2, characterized in that the lower, branching off from the heated container channel (k) is connected to the lower end of the tube (e) of small inside diameter near its connection with the knee-shaped bent tube (d) . 5. Pump according to claim 2 and 4, characterized in that the upper end of the tube (e) has a small inside diameter, a downwardly extending, acting as a capacitor extension (0). 6. Pump according to claim 2, characterized in that the mouth of the pipe supplying the cold liquid is designed as an injector (q) . 1 sheet of drawings