DE4320343A1 - Heat exchanger, in particular a cross-flow cooler, (radiator, cooling heat exchanger) for internal combustion engines - Google Patents

Abstract

The compensating tanks (level vessels) of known cross-flow coolers are arranged parallel to one of the two tanks (cooling-water reservoirs). It is not possible to install such cross-flow coolers when building conditions are restricted. It is proposed to arrange the compensating tank exclusively in the region of the inflow nozzle arranged above one tank and to connect it via a channel (duct, conduit) opening in the region of the highest point of the compensating tank to the inlet chamber behind the inflow nozzle, to separate this inlet chamber from the interior of the tank by a restricting wall (baffle) which releases a smaller flow cross-section than the flow cross-section of the inflow nozzle, in order finally to connect the compensating tank in its lower region via an opening to the interior of the tank, which connection ends behind the restricting wall in the flow direction. The effect of this configuration is a positive venting (discharging, deaerating, purging) flow in the compensating tank without the need for further separate measures at the tanks. Use for cross-flow coolers in internal combustion engines of commercial vehicles. <IMAGE>

Description

The invention relates to a heat exchanger, in particular one Cross-flow cooler for internal combustion engines with one on both sides Finned tube block arranged water boxes and with an off expansion tank for the coolant, the first, on his upper end with a water inlet is ordered.

Heat exchangers of this type are known (EP 0 184 197 B1). At In these types, the inlet pipe opens into the upper area of the first water box laterally in this. The water box itself is parallel to its longitudinal axis Partition provided inside, that of the tube sheet opposite is assigned to the lying side of the water tank. This separation wall separates you from top to bottom in the water tank running channel, which in its lower area via a ver connector in one piece with the water tank provided lower part of a surge tank opens. The waiter part of the expansion tank is designed to be transparent to be able to observe the level.

It is also known (DE 33 41 390 A1, Fig. 4) to assign an expansion socket provided with a water outlet to a roughly parallel expansion tank, but not with the interior of this water tank, but via a separate pipe that penetrates the finned tube block from the other What serkasten is in connection with the coolant, and there too - in the water box opposite the first water box - a partition is raised in the upper area, which forms a channel, which in turn is in connection with the previously mentioned pipe. In this design, however, there is also the outlet nozzle on the first water tank, so that there is a U-shaped flow through the finned tube block, which is also caused by the arrangement of corresponding partitions in the first water tank. In both cases, the expansion tanks go through about the entire height of the water tanks. This also applies to versions (DE 33 41 390 A1, Fig. 1) where the expansion tank is assigned to the water box provided with the spout. Heat exchangers of this type cannot always be used in the often cramped installation spaces in motor vehicles. The assignment of the expansion tank to the water tank with the drain is not always possible.

The invention is therefore based on the object of heat exchanger, in particular a cross flow cooler of the beginning named type so that the expansion tank does not take up space over the entire height of the water tank, but nevertheless the guarantee of adequate ventilation of the Coolant in the expansion tank and sufficient Flow through the expansion tank is guaranteed.

To solve this problem it is proposed that the off expansion tank only in the area next to the inlet arranged and over one in the area of the highest point of the expansion tank opening with the entry space is connected behind the inlet connection that the entry space from the interior of the water tank through a throttle wall is separated, which releases a smaller flow cross-section than the flow cross-section of the inlet connection, and that the Expansion tank in its lower area via a  Opening in connection with the interior of the water tank stands, which opens behind the throttle wall in the direction of flow. This configuration is in the entry space behind the Inlet connection inevitably a higher pressure of the coolant than evoked in the rest of the water tank area, the a forced flow in the highest area of the off equal container opening channel. In the enema air entering will therefore clutter as the duct goes up leads with the current taking place there and gets into the upper area of the expansion tank that is on this way only at the top of the inlet water box needs to be arranged and therefore no additional occupies the space next to one of the water tanks.

An advantageous development of the invention provides that the throttle wall is transverse to the longitudinal axis of the water tank is the dividing wall protruding towards the tube sheet, which in a certain distance that determines the flow cross-section ends in front of the tube sheet. By choosing this distance leaves the basic volume of the equalization intended for air holder, which is usually above the upper tube of the Finned tube block, influence. The distance is therefore expediently chosen so that a sufficient in operation large volume of air is in the expansion tank, through which the coolant level is also regulated accordingly.

A development of the invention provides that the one through a channel leading into the expansion tank Wall running parallel to the outer wall of the expansion tank is formed, which is integral with the expansion tank and the Entry space is made. With this configuration, simply the desired channel cross-section he on the other hand, the production is also a very subject.  

The inlet connector can be on the side of the expansion tank be brought, the expansion tank advantageously a parallel to the longitudinal axis of the water tank Has a separation surface on which a cover with the inlet socket is welded on. This configuration enables one-piece production of water tank and expansion tank ter. Finally, there is a particularly space-saving solution management form for the heat exchanger if the drain socket for the coolant at the bottom of the one with the balancing container-facing water box opposite water box is attached. This configuration, in which there is no U flow through the cross-flow cooler both water tanks free of most of their length outer accessories, and the expansion tank is only one assigned to the water tank in the upper area. The installation space for such a heat exchanger can therefore be kept very small become.

The invention is based on an embodiment in the Drawing shown and is explained below. It demonstrate:

Fig. 1 is a schematic view of a cross-flow radiator according to the invention for an internal combustion engine, in particular for a utility vehicle,

See Fig. 2 is a view of the cross-flow cooler of Fig. 1 in the direction of the arrow II,

Fig. 3 is an enlarged view of the upper portion of the cross-flow radiator according to the invention in the view according to Fig. 2, but with raised end cover to gain insight into the surge tank to equip ge,

Fig. 4 cut the section through the expansion tank of FIG. 3 in the direction of line IV-IV, and

Fig. 5 cut the section through the expansion tank of FIG. 3 in the direction of the line VV.

In Figs. 1 and 2, a cross-flow radiator is shown which consists of a ribbed tube block (1) with horizontal tubes and between the tube axis (2) extending ribs is constructed perpendicular, which is not shown in detail. The tubes are each held in a known manner in tube sheets ( 3 ) and ( 4 ), of which the tube sheet ( 4 ) is attached to a first water tank ( 5 ) and the tube sheet ( 3 ) to a second water tank ( 6 ). The first water tank ( 5 ) is finally assigned an expansion tank ( 7 ) in the upper area, which consists of a piece molded with the water tank NEN or sprayed expansion tank part ( 7 a) and a cover welded onto this along a separating surface ( 8 ) 9 ), which is provided with an inlet connection ( 10 ) for the coolant. This inlet connector ( 10 ) can be integrally formed with the end cover ( 9 ). In the exemplary embodiment, however, it consists of a separate connecting piece which is attached to the separating surface ( 8 ) in a manner not shown, in particular is welded.

In contrast to known heat exchangers, the inlet nozzle ( 10 ) is therefore not directly assigned to the water tank ( 5 ), but rather to the expansion tank ( 7 ) arranged in one piece on this water tank ( 5 ). Figs. 1 and 2 show, first, that the cross-flow cooler (1) is freely share according to the invention over the largest area of its two water tanks (5 and 6) of cultivation. The flow through the crossflow cooler ( 1 ) takes place from the inlet connection ( 10 ) and the water tank ( 5 ) to the water tank ( 6 ). The coolant then leaves the cross-flow cooler ( 1 ) through a drain pipe ( 12 ) which is provided on the underside of the water box ( 6 ). A filler neck ( 13 ) is associated with the expansion tank ( 7 ) in a known manner. Both water tanks ( 5 and 6 ) are provided with pins ( 14 and 15 ) protruding from the end for attachment to the vehicle.

In order to achieve the required ventilation of the inlet pipe ( 10 ) to flow coolant, as shown in FIGS. 3 to 5, the one with the water tank ( 5 ) integrally connected part ( 7 a) of the expansion tank ( 7 ) in particular Trained way.

Fig. 3, in which the end cover ( 9 ) and the connecting piece ( 10 ) is omitted, shows that behind the inlet pipe ( 10 ) an entry space in the form of up to the interior of the water box ( 5 ) above the not shown tube sheet ( 4 ) through shaft ( 16 ) is provided. The water shaft ( 16 ) opens into the interior of the water tank ( 5 ) so that the coolant flows into the water tank ( 5 ) in the direction of the arrows ( 17 ). FIGS. 3 to 5 show that the water tank (5) projects into the connecting path between the shaft (16) and the interior (18) a throttle wall (19) than transversely to the longitudinal axis (20) of the water tank (5 ) standing, from the expansion tank part ( 7 a) to the tube bottom ( 4 ) protruding transverse wall is formed. This Dros selwand ( 19 ) has in the embodiment a parallel to the tube sheet ( 4 ) running lower edge, which opens at a certain distance (a) in front of the tube sheet ( 4 ). This distance (a), together with the other dimensions of the flow channel ( 21 ) in the region of the throttle wall ( 19 ), determines the flow cross section for the coolant. The distance (a) is chosen so that the flow cross-section released by the throttle wall ( 19 ) is smaller than the inlet cross-section of the inlet connection ( 10 ). By this measure, a certain overpressure builds up in the shaft ( 16 ) compared to the pressure in the interior ( 18 ) of the water tank ( 5 ), which, as will be explained below, is used to force a flow directly behind the inlet connection in the expansion tank cause air in the coolant entrained by the inlet connection ( 10 ) to settle in the expansion tank ( 7 ).

From Figs. 3 and 4 (also FIG. 2 suggestively) shows that the shaft (16) merges in its upper region in a narrow channel (22) formed by a parallel to the outer wall (7 b) of the compensating container part ( 7 a) extending wall ( 23 ) is formed which ends below the upper end of the expansion tank ( 7 ) forming approximately horizontal wall part ( 7 c). The channel ( 22 ) therefore leads from the shaft ( 16 ) upwards in a slight curvature and ends just below half of the ceiling wall ( 7 c).

Since, as previously explained, there is an increased pressure in the shaft ( 16 ) due to the arrangement of the throttle wall ( 19 ), part of the coolant is inevitably passed through the channel ( 22 ) into the inner space ( 24 ) of the expansion tank ( 7 ) and in the sense of the arrows ( 25 ) led to an opening ( 26 ) which is located in an approximately perpendicular wall surface of the expansion tank ( 7 ) immediately behind the throttle wall ( 19 ). This opening ( 26 ) communicates with the interior ( 18 ) of the water tank ( 5 ). The forcibly guided through the channel ( 22 ) coolant therefore passes after flowing through the expansion tank also in the cooling circuit, in which the coolant entered in the sense of arrows ( 17 ) through the cross section below the throttle wall ( 19 ). The coolant then, as previously stated, from the water tank ( 5 ) to the water tank ( 6 ) and leaves the cross-flow cooler through the drain port ( 12 ).

The design is carried out so that the water level ( 27 ) in the expansion tank ( 7 ) is still above the uppermost pipe of the water tank ( 5 ), not shown, so that entrainment of air into the cooling circuit is prevented. The position of the liquid level ( 27 ) can be influenced by the distance (a) of the lower edge of the throttle wall ( 19 ) from the tube sheet ( 4 ). It is very clear from Fig. 3 that in the expansion tank ( 7 ) is a sufficiently large volume of air above half of the coolant level ( 27 ).

Due to the inventive design, the inlet water box ( 5 ) is preceded by an expansion tank, which is finally arranged in the area of the inlet connection ( 10 ) and the coolant flow entering through this inlet connection ( 10 ) even before reaching the interior ( 18 ) of the water tank ( 5 ) in a forcibly circulating partial ventilation stream and divides an inlet. Since the ventilation is carried out by the arrangement of the channel ( 22 ) upwards, the Ge is given for adequate ventilation. The compensation tank ( 7 ) can be molded in one piece on the water tank ( 5 ). Due to its arrangement only in the upper part of the same, both water boxes ( 5 ) remain completely free of laterally protruding parts over most of their length. The new cross-flow cooler can therefore be used advantageously where there is no space for the lateral arrangement of an expansion tank in a cross-flow cooler.

Claims (7)

1. Heat exchanger, in particular cross-flow cooler for internal combustion engines with both sides of a finned tube block ( 1 a) on ordered water tanks ( 5 , 6 ) and with an expansion tank ( 7 ), which is provided with an inlet connection ( 10 ) for the coolant at its upper end ( 5 ) is assigned, characterized in that the expansion tank ( 7 ) is finally arranged in the area next to the inlet connection ( 10 ) and via a channel ( 22 ) opening into the area of the highest point of the expansion tank ( 7 ) with the inlet space ( 16 ) is connected behind the inlet nozzle that the inlet space ( 16 ) from the interior ( 18 ) of the water tank ( 5 ) is separated by a throttle wall ( 19 ) which releases a smaller flow cross-section than the flow cross-section of the inlet nozzle ( 10 ) and that the expansion tank ( 7 ) in its lower region via an opening ( 26 ) with the interior ( 18 ) of the water tank ( 5 ) is connected, which opens in the flow direction behind the throttle wall ( 19 ). 2. Heat exchanger according to claim 1, characterized in that the inlet space behind the inlet connection ( 10 ) is designed as a shaft ( 16 ) which leads into the area of the interior ( 18 ) of the water tank ( 5 ), but from this the throttle wall ( 19 ) is separated. 3. Heat exchanger according to claim 1 or 2, characterized in that the throttle wall ( 19 ) is a transverse to the longitudinal axis ( 20 ) of the water tank ( 5 ), to the tube sheet ( 4 ) protruding partition, which in a certain, the distance (a) determining the flow cross section opens in front of the tube sheet ( 4 ). 4. Heat exchanger according to claims 1 and 2, characterized in that the from the shaft ( 16 ) in the expansion tank ter ( 7 ) leading channel ( 22 ) through a parallel to the outer wall ( 7 b) of the expansion tank ( 7 ) guided Wall ( 21 ) is gebil det, which is made in one piece with the expansion tank ( 7 ) and the shaft ( 16 ). 5. Heat exchanger according to one of claims 1 to 4, characterized in that the inlet connection ( 10 ) is attached to the side of the expansion tank ( 7 ). 6. Heat exchanger according to claim 5, characterized in that the expansion tank ( 7 ) has a parallel to the longitudinal axis ( 20 ) of the water tank ( 5 ) extending separating surface ( 8 ) on which an end cover ( 9 ) with the inlet connection ( 10 ) is welded on. 7. Heat exchanger according to one of claims 1 to 6, characterized in that the drain pipe ( 12 ) for the cooling medium is attached to the underside of the water tank ( 5 ) provided with the expansion tank ( 7 ) opposite water tank ( 6 ).