DE10050852A1 - Cooling water expansion tank for cooling water circuit of motor vehicles has round circumferential wall, and inlet pipe connector enters tank tangentially - Google Patents

Abstract

The cooling water expansion tank has a round circumferential wall, and the inlet pipe connector (4) enters the tank tangentially. The expansion tank may have a spherical or cylindrical form. The inlet pipe connector may be inclined downwards. A deflector may be installed in the entry region of the inlet connector to deflect the cooling fluid to the inside wall of the expansion tank. The end section of the inlet pipe connector may have an increased cross section.

Description

The invention relates to a cooling water expansion tank an inlet pipe opening into its upper area, through which the coolant in the cooling water expansion tank ter enters, and a suction nozzle arranged on the floor, through which the coolant is pumped out of the coolant water expansion tank is suctioned off again.

Such cooling water expansion tanks are in the cooling water circuit arranged by motor vehicles and have a buffer volume from air, the volume change of the coolant z. B. as a result changes in temperature, different hose expansions etc. compensates.

In addition, air should accumulate in the cooling water expansion tank in the coolant in the form of larger or smaller gas bubbles are deposited, otherwise the efficiency of the Cooling system would deteriorate significantly.

With the cooling water expansion tanks previously encountered the inlet connector is attached perpendicular to the tank wall, whereby the coolant entering at high speed fron valley on the surface of the liquid inside the container meets. This leads to considerable foam formation, which is partially sucked in by the water pump. It is also  then the case when the incoming coolant jet is on a baffle is steered, as is the case with conventional cooling water reservoirs is often the case.

The present invention has for its object a Specify the cooling water expansion tank in which the coolant degassing is more effective.

This object is achieved by the features of Pa claim 1 solved.

Advantageous embodiments of the invention are in the sub claims marked.

The invention provides that the cooling water expansion tank has a circular peripheral wall and that the inlet connector about opens tangentially into the cooling water expansion tank. at In this configuration, the cooling liquid is along the inside wall of the cooling water expansion tank led, according to one or more turns on the liquid surface in the cooling water expansion tank and in there accumulated liquid enters. By flowing along the The inner wall of the container is the formation of gas bubbles or foam significantly reduced.

For reasons of strength, it is preferred that the cooling water expansion tank has a substantially spherical shape. there but is also, for example, a circular cylindrical shape tion within the scope of the invention.

It is also proposed that the inlet nozzle in the tip Angle to the horizontal is inclined downwards and that in loading a guide wall extends from the mouth of the inlet connector is arranged, which is the current flowing from the confluence of the one coolant leaked to the inner wall of the Cooling water expansion tank steers. Through suitable training  the guide wall can be achieved that the entire one led coolant flows along the inner wall.

This further reduces the formation of gas bubbles ren that after a further proposal of the invention the end section of the inlet nozzle a constantly increasing Receives cross section, causing the exit velocity of the Coolant is reduced. This promotes the degassing of the Liquid while flowing along the peripheral wall and prevents blistering when hitting the surface the accumulated liquid in the container.

According to a further essential proposal, it is provided that itself in the lower area of the cooling water expansion tank Plate extends almost over the entire interior. This Plate is arranged at about 1/4 the height of the container and serves the purpose of preventing gas bubbles in the area of Ab the suction nozzle when bathing the container.

In more detail, this important feature is featured see that between the plate and the inner wall of the cooling water compensating container ver a gap over a circumferential area remains of either a substantially constant width of for example, has about 5 mm or its width preferably in The direction of rotation of the liquid increases.

This gap expediently extends approximately over the Half of the circumference, with the plate in the remaining area preferably on the inner wall of the cooling water expansion tank is welded on.  

It is also proposed with particular advantage that the plate has a flat cone shape with an inclination angle of at for example 10 to 20 °, and that in the center a vertically upwards protruding degassing nozzle is attached by the gas that got under the plate, up into the air area of the Cooling water expansion tank emerges. So that all bubbles transported upwards so that the extracted coolant is practically gas-free.

The shape and size of the cooling water expansion tank depends on other of the respective spatial conditions in the engine compartment a motor vehicle. In addition to the one-chamber Cooling water expansion tanks are also available in multi-chamber systems which the interior of the cooling water expansion tank through Interior walls are divided into several chambers that pass through openings are connected. The coolant enters a first chamber and passes through others Chambers into the outlet chamber from which it is sucked off.

According to a further proposal of the invention, the above forms described cooling water expansion tank a chamber Multi-chamber system, namely the Kammar, in which the coolant speed is introduced through an inlet nozzle. The fiction the circular circumferential wall provided limits the Inlet chamber of a z. B. cubic cooling water expansion tank ters, which contains several other chambers through internal walls separated from one another and connected to one another via passages are. The coolant emerges from a lower Be range of the inlet chamber - preferably below a gas trap plate - trained passage opening one after the other Most chambers that hold the coolant at a time Chen give degassing before the coolant from the last Chamber is suctioned off.

Further details of the invention emerge from the following description of preferred embodiments of the cooling water expansion tank and based on the drawing. Show in a purely schematic way:

Figure 1 is a vertical section through a spherical cooling water expansion tank, partially shown in view.

Fig. 2 shows a horizontal section through a multi-chamber cooling water expansion tank with a cylindrical inlet chamber and

Fig. 3 is a vertical section along the line AA in Fig. 2, partially shown in view.

Fig. 1 shows a spherical cooling water expansion tank 1 , which is composed of two half-shells 2 , 3 . An inlet connection 4, enters through which the cooling liquid in the tank equal Kühlwasseraus 1, opens tangentially in the coolant expansion tank 1, where the inlet nozzle 4 is slightly inclined downwards, as shown in Fig. 1. Fig.

In the cooling water expansion tank 1 , a plate 5 is arranged in its lower region, which has a flat conical shape that rises slightly towards the central axis 6 . A degassing nozzle 7 is attached to the plate 5 concentrically to the central longitudinal axis 6 and extends into the upper air area in the interior of the cooling water expansion tank 1 .

The plate 5 is applied over a circumferential area, which depends on the respective conditions, on the wall of the lower half-shell 3 , for example welded, while in the remaining circumferential area a gap 8 remains between the container wall and the edge of the plate 5 .

The cooling water expansion tank 1 has a suction nozzle 9 through which the cooling liquid leaves the container 1 .

The upper region of the cooling water expansion tank is closed by a cover 10 , the details of which are not of interest in connection with the present invention.

That in the cooling water expansion tank with about 1.0 to 1.4 bar cooling medium entering in an amount of up to about 5 l / min flows down along the inside wall of the container and can cover several turns until it reaches the top of the liquid Area in the cooling water expansion tank reached. Doing so the gas-containing liquid is highly degassed.

If the cooling liquid passed through the gap 8 under the plate 5 still carries gas with it, this rises to the center of the plate and is led up through the degassing nozzle 7 into the air region of the cooling water expansion tank 1 . The liquid sucked through the nozzle 9 is practically gas-free.

Fig. 2 shows - also purely schematically - a multi-chamber cooling water expansion tank 16 consisting of five chambers. The inlet chamber 17 , which is shown in vertical section in FIG. 3, has a cylindrical shape. The coolant passes through the inlet nozzle 4 again in the tangential direction into the interior of the chamber 17 and flows - as in the embodiment according to FIG. 1 - down along the circular chamber wall to through the slot 8 between the plate 5 and the wall of the chamber 17 to step through. Any entrained gas is here abge leads through the degassing 7 in the upper air area.

The highly degassed cooling liquid thus passes through an opening 18 formed in the bottom area in the wall of the chamber 17 into the subsequent chamber 19 and subsequently through further outlet openings into the chambers 20 , 21 and 22 , from which the cooling liquid is sucked out through an outlet connection 23 .

Claims (10)

1. cooling water expansion tank with an opening in its upper area, through which the cooling liquid speed enters the cooling water expansion tank, and an outlet opening arranged at the bottom through which the cooling liquid leaves the tank, characterized in that the cooling water expansion tank ( 1 ) has a circular peripheral wall and that the inlet connection ( 4 ) opens approximately tangentially into the cooling water expansion tank ( 1 ). 2. cooling water expansion tank according to claim 1, characterized in that it has a spherical shape. 3. cooling water expansion tank according to claim 1, characterized in that it has a cylindrical shape. 4. Cooling water expansion tank according to one of claims 1 to 3, characterized in that the inlet connector ( 4 ) is inclined downwards. 5. Cooling water expansion tank according to one of claims 1 to 4, characterized in that a deflector is arranged in the region of the confluence of the running nozzle ( 4 ), which directs the Kühlflüs liquid to the inner wall of the cooling water expansion tank ( 1 ). 6. Cooling water expansion tank according to one of the claims 1 to 5, characterized in that the end portion of the inlet nozzle has an enlarged cross section.   7. cooling water expansion tank according to one of claims 1 to 6, characterized in that in the lower region of the cooling water expansion tank ( 1 ) a plate ( 5 ) extends almost over its entire cross section. 8. cooling water expansion tank according to claim 7, characterized in that between the plate ( 5 ) and the inner wall of the cooling water expansion tank ( 1 ) over a circumferential region, a gap ( 8 ) remains. 9. cooling water expansion tank according to claim 7 or 8, characterized in that the plate ( 5 ) has a flat conical shape with a central, vertically upwardly projecting degassing nozzle ( 7 ). 10. cooling water expansion tank according to one of claims 1 to 9, characterized in that the cooling water expansion tank is a chamber ( 17 ) of a multi-chamber cooling water expansion tank ( 16 ).