DE3205831A1 - Vacuum liquid suction device - Google Patents

Abstract

A vacuum liquid suction device has an upright container (12) which has, laterally, a suction nozzle (22) above the greatest filling height and is sealed vacuum-tightly to the outside by a lid (15) at the top, suction turbines (28) being arranged in the region above the greatest filling height and preferably in the lid via filters, and a sensor (11) for determining the greatest filling height extending from above, preferably from the lid. To prevent a false reading due to liquid spraying round, provision is made for a heated electronic temperature sensor (11) to be accommodated in a bell-like housing (13) and to be situated in the region of the greatest filling height (H) in the container (12). <IMAGE>

Description

The invention relates to a vacuum liquid suction device

with an upright container, which is above the largest Filling level has a suction nozzle on the side and vacuum-tight at the top by a lid is closed to the outside, being in the area above the largest filling level and suction turbines are preferably arranged in the cover over filters and are located from above, a sensor for determining the maximum filling level preferably extends from the cover.

Such vacuum liquid suckers generally have a circular cylindrical shape Container with a flat bottom, which is mounted on rollers for the purpose of drivability can be. The suction port opens into the side wall of the container in the upper half of the same, so that with up to the lower edge of the intake manifold when the container is completely filled with liquid, a certain amount Air space remains between the lid and the surface of the liquid. Once the fluid level has reached the lower edge of the intake port, they should preferably be at the top one and, in particular, two suction turbines arranged on the cover are automatically switched off to a too high level and thus a leakage of the liquid from the Avoid intake manifold after switching off. In known vacuum liquid suction devices float balls located in the container are used for this purpose, which if the liquid level is too high in front of the circular inlet opening of the suction turbine and thus seal them tightly. The suction turbines then continue to run, but can no longer pass suction into the interior of the container. Disadvantage of this known method, however, is that the float balls due to the suction turbine inlet frequently do not seal sufficiently from impurities, so that liquid remains is sucked in beyond the permissible filling level.

Mechanical liquid level indicators have the disadvantage that they can easily be damaged when the cover is removed and otherwise by corrosion or impurities in the sucked-in water or foam impair their function can be.

Optical and electrical liquid level measurement methods are used in vacuum liquid suction devices cannot be used with success because it is always considerable during operation of the vacuum cleaner Amount of liquid, spray and foam above the surface of the liquid in the container whirl around, which optical or electrical but also mechanical liquid level sensors to respond too early, so that the suction turbines are already switched off, before the maximum filling level is reached.

The aim of the invention is thus to provide a vacuum liquid suction device of the type mentioned at the beginning, which is independent of the operation In the air space of the container swirling amounts of liquid a switch-off signal for the suction turbine or the suction turbines only releases when the liquid level has reached the specified maximum value in the container.

To solve this problem, the invention provides that a heated electronic temperature sensor is housed in a bell-shaped housing and is in the area of the highest filling level in the container the temperature sensor inside the bell-shaped housing, which is open at the bottom, against the swirling liquid splashes in the air space of the container effectively protected, which because of the lateral inflow of the liquid or foam from the Side of the container always only from the side or from above onto the bell-like Encounter housing, so that the sensor located inside the bell only then comes into contact with liquid when the liquid level is inside the container has risen so high that it reaches the feeler. The temperature sensor will above a control unit is heated to a certain temperature during operation. As soon as the liquid level reaches the temperature sensor, it becomes accordingly cooled, which then causes a change in current, which the switch-off signal in the control unit As soon as this switch-off signal appears, the suction turbine (s) will switched off. The temperature sensor is conveniently located in the lowest area of the bell-like housing, but still so far above its lower edge, that splashes cannot normally reach the feeler.

The suction turbines and the control device of a vacuum liquid suction device according to the invention are usually placed on top of the lid of the container and with this from Removable container. For this reason, it forms the one containing the temperature sensor bell-like housing part of the lid.

In order to avoid the connecting means when removing and putting down the cover between the lid and the bell-like housing damage is after a Another embodiment, the housing over a vertically upwardly extending flexible hose connected to the lid. The flexibility of the hose is supposed to be such that it is up to a right angle from its perpendicular to the lid Normal position is elastically bendable.

In this way, the hose carrying the housing gives way when it is put down of the lid simply to the side without it, the bell-like housing or the Temperature sensor could be damaged. The diameter or the transverse extent the interior of the bell-like housing according to the invention is expediently so small that the temperature sensor cannot be accidentally penetrated by foreign bodies can be damaged from below into the housing.

It is best if the width or the diameter of The interior is only so large that the temperature sensor and its supply line are straight have space in it.

A particularly expedient structural embodiment is characterized in that the hose is passed through a hole in the bottom of the bell and is attached there preferably by gluing.

For manufacturing, structural and functional reasons it is also advantageous if the housing has a circular cylindrical shape with a vertical Axis has.

The interior of the housing, which is open at the bottom, is also preferred be circular cylindrical, making it not only easy to manufacture, but also offers optimal spatial conditions for the temperature sensor.

Furthermore, the retaining hose provided according to the invention is expedient used to accommodate the electrical lead to the temperature sensor. Preferably the supply line does not completely fill the interior of the hose, so that the side Bending the hose effectively prevents damage to the electrical supply line is.

This means that when the highest filling level is reached, the liquid is safe reaches the temperature sensor, should be in the upper area of the interior of the housing there must be at least one air outlet hole. It is particularly useful if-an air outlet hole is provided in the upper area of the side wall of the container is because this creates the risk of splashing liquid penetrating through the air outlet hole is reduced.

This risk is further reduced by the fact that the air outlet hole on the one facing away from the intake manifold Side of the side wall of the Container is provided.

So not from the one diametrically opposite the intake manifold Liquid that has bounced off the wall can penetrate into the air outlet hole, that should bell-like housing at a diametrical distance corresponding to 0.6 to 0.9 times, in particular 0.75 times the diameter or wall distance of the container from Be arranged intake manifold.

So that it has a larger diameter than the hose The upper surface of the bell-like housing does not collect any liquid and thereby may enter the interior of the housing through the air outlet hole can, the top surface of the case is supposed to be in a runoff of impinging Be beveled roof-like dimensions to allow liquid. In particular, the Surface an inclined plane The angle of the inclined surface (s) to the horizontal 15 to 450 and especially about 350.

It is particularly important that the inclined surface (s) is directed in this way (are) that incident liquid only flows off in such areas of the side wall, where there is no air outlet hole.

A particularly compact and easy to manufacture embodiment is characterized in that the upper surface formed as an inclined plane of the housing from a highest point on the side of the air outlet hole to opposite side facing the intake manifold falls.

The cooler should be at a small safety distance below the be arranged lower edge of the intake so that the liquid level the height of the suction nozzle even if the container is perhaps a little crooked can not achieve.

The invention is illustrated below, for example, with reference to the drawing described; 1 shows a partially sectioned schematic side view a vacuum liquid suction device according to the invention, FIG. 2 a View of the cover of the vacuum liquid suction device according to the invention from below and 3 shows the detail III of FIG. 1 indicated by dash-dotted lines on an enlarged scale Scale.

According to FIGS. 1 and 2, the vacuum liquid suction device according to the invention a circular cylindrical container 12 made of stainless steel, which is supported on the floor 25 via rollers 24. In the upper third of the container is in the side wall a suction port 22 is provided on which a flexible suction hose 26 is attached, of which only a short piece is shown. The suction hose is generally a few meters long and has a suitable one at its free end Provide suction nozzle.

At the top is the container 12 through a tightly fitted lid 15 closed, which by means of fastening means 27, which are only indicated schematically is held releasably.

According to FIGS. 1 and 2, two suction turbines are next to each other on the cover 28 arranged, which the lid 15 tight take action and on that Inside the container 12 arranged turbine part with seven closed circular Have suction openings 29.

When the suction turbine 28 is running and the cover 15 is in place, the container 12 creates a negative pressure, due to which liquid or foam, but also dust or other impurities through the suction hose 26 into the interior of the Container 12 can be sucked.

According to the invention, there is also an electronic control device on the cover 30 arranged, by means of which the suction turbines 28 switched on and off by hand can be. The control unit 30 is also connected to a temperature sensor 11, which is heated by the control unit 30 and via a suitable electronic Circuit 31 in control unit 30 trigger a shutdown signal for suction turbines 28 can if it is cooled by immersion in a liquid.

The temperature sensor 11 is preferably a two-wire electrical Feed line 16 through a bore 32 in the cover 16 with the control unit 30 tied together. The supply line 16 is preferably surrounded by a distance on all sides an elastic flexible hose 14 which is glued tightly into the bore 32 is. According to FIGS. 1 and 3, the lower end of the flexible hose 14 is in a Bore 17 fitted in the bottom 18 of a bell-like housing 13 and there with a suitable adhesive. In this way, the electrical lead 16 out into the interior 20 of the housing 13, where in the lower area of the temperature sensor 11 is arranged.

The length of the elastic extending perpendicular to the cover 15 flexible hose 14 and the housing 13 are such that when the lid is in place 15 the temperature sensor 11 at such a distance from the ground of the container 12 is located, as is the maximum permissible filling height H of the container is equivalent to. This maximum filling level is around a small safety distance A. below the lower edge of the intake port 22.

The housing 13 is machined from a circular cylindrical filler material. The interior 20 represents an axial circular cylindrical bore, whereby a circular cylindrical side wall 19 is formed. The bottom 13 is with a one Provided the inclined plane 23 forming upper surface, such as that in FIGS. 1 and 3 is shown. The surface 23 is beveled in such a way that incident from above Liquid drains from the housing 13 in the direction of the suction port 22.

In the upper area of the side wall 19 is located on the intake manifold 22 facing away from the side of the container 13 an air outlet hole 21, which ensures that the liquid level within the bell-like housing 13 in the off Fig. 1 can rise up to the level of the temperature sensor 11 as can be seen. As soon as this has been done according to FIG. 1, the control unit 30 switches the suction turbines 28 and another suction process is avoided.

An indicator lamp 33 in control unit 30 can display this state bring.

Due to the arrangement shown, none can be used when operating the vacuum cleaner fluid swirling around in the air space reaches the temperature sensor 11, so that no premature switch-off signal is triggered. Due to the special arrangement the air outlet hole 21 and the inclined surface 23 is also ensured that the water draining from the upper surface 23 of the housing 13 does not pass through the Air outlet bore 21 penetrates into the interior of the housing 13.

If that is desired, the air outlet bore 21 could also be included be drilled from the inside to the outside sloping axis 34, as shown in Fig. 3 is indicated schematically. This reduces the tendency for liquid to pass through the air outlet bore 21 penetrates into the interior 20, further reduced. Finally, drip projections 35 above the air outlet bore could also be used for the same purpose 21 are attached to the housing 13, as indicated in Fig. 3 ah.

As soon as the container 12 is filled with liquid up to the level H, Thus, the control device 30 controlled by the temperature sensor 11 switches the suction turbines 28 and the warning lamp 33 comes on. Now the lid with the attached Aggregates are removed and set aside, whereupon the container 12 at suitable Body is emptied.

The cover 16 can easily with its underside on a be placed on a flat surface, because here the flexible hose 14 is positioned laterally can evade, so that neither the bell-like housing 13 nor the electrical Feed line 15 can be damaged.

After the cover 15 is raised again, the hose moves 14 automatically in its position perpendicular to the cover 15, so that the temperature sensing arrangement is immediately operational again.

In Figs. 1 and 2, the suction port 22, the suction hose 26 and the temperature measuring arrangement shown exaggerated in size to the better show essential details.

The temperature sensor 11 is with a low voltage of 6, 12 or 24 V operated.

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Claims (17)

Vacuum liquid suction device Patent claims Ö vacuum liquid suction device with an upright container, which is above the largest filling level on the side has a suction port and vacuum-tight to the outside through a cover at the top is completed, in the area above the largest filling level and preferably Suction turbines are arranged in the cover over filters and are located from above, preferably extends from the lid of a sensor to determine the largest filling level, thereby it is not indicated that a heated electronic temperature sensor (11) is housed in a bell-like housing (13) and is located in the area the highest filling level (H) is in the container (12). 2. Vacuum liquid suction device according to claim 1, characterized in that g e -k e n n z e i c h n e t that the housing (13) over a vertically upwardly extending flexible and preferably also elastic hose (14) with the Lid (15) is connected. Vacuum liquid suction device according to claim 2, characterized in that g e -k k e n n z e i c h n e t that the electrical lead (16) to the temperature sensor (11) through a hole in the cover and through the hose (14) is passed. 4. vacuum liquid suction device according to claim 2 or 3, characterized g e k It is noted that the hose (14) passes through a hole (17) in the base (18) the bell (13) passed through and fixed there preferably by gluing is. 5. Vacuum liquid suction device according to one of the preceding claims, in that the housing (13) is circular-cylindrical Has a shape with a vertical axis. 6. Vacuum liquid suction device according to one of the preceding claims, characterized in that the downwardly open interior (20) of the Housing (13) is circular cylindrical. 7. Vacuum liquid suction device according to one of the preceding claims, characterized in that in the upper area of the interior (20) of the housing (13) there is at least one air outlet bore (21). 8. Vacuum liquid suction device according to claim 7, characterized in that g e -k e n n z e i c h n e t that an air outlet hole (21) in the upper area of the side wall (19) of the housing (13) is provided. 9. Vacuum liquid suction device according to claim 8, characterized in that g e -k e n n show that the air outlet hole (21) is on the one from the intake port (22) facing away from the side wall (19) of the container (13) is provided. 10. Vacuum liquid suction device according to claim 9, characterized in that g e -k e n n z e i c h n e t that the housing (13) at a diametrical distance accordingly 0.6 to 0.9 times, in particular 0.75 times, the diameter or wall distance of the container (12) from the suction port (22) is arranged. 11. Vacuum liquid suction device according to one of the preceding claims, characterized in that the upper surface (23) of the housing (13) roof-like to an extent that allows the liquid to run off is abraded. 12. Vacuum liquid suction device according to claim 11, characterized in that g e -k e n It should be noted that the surface (23) is an inclined plane. 13. Vacuum liquid suction device according to claim 11 or 12, characterized g e it does not indicate that the angle of the inclined surface (s) (23) to the horizontal 15 to 450 and in particular about 35 °. 14. Vacuum liquid suction device according to one of claims 8 to 10 and 11 to 13, characterized in that the inclined surface (s) (23) so is directed, (are) that impinging liquid only in such areas of the Sidewall (19) flows off where there is no air outlet hole (21). 15. Vacuum liquid suction device according to claim 8, 12 and 14, characterized in that g It is not noted that the upper surface formed as an inclined plane (23) of the housing (13) from a highest point on the side of the air outlet hole (21) drops to the opposite side facing the intake port (22). 16. Vacuum liquid suction device according to one of the preceding claims, in that the sensor (11) is at a small safety distance (A) is arranged below the lower edge of the intake port (22). 17. Vacuum liquid suction device according to one of claims 2 to 16, characterized it is noted that the flexibility of the hose (14) is such that that it is up to a right angle from its normal position perpendicular to the cover (15) is elastically bendable.