DE1997943U - SEALED COOLING DEVICE FOR COMBUSTION MACHINERY. - Google Patents

Description

"Sealed cooling device for internal combustion engines"

For this registration, the priority of registration will be Ser.Uo. 355 727 dated March 30, 1964- in the United States of Hord America claimed.

The innovation "refers to a sealed cooling device for internal combustion engines and in particular to a sealed one Cooling device, "in which air is in contact with your coolant is excluded in a new way.

The need for low maintenance automobiles created the demand for a ¹ sealed coolers. In liquid-cooled internal combustion engines, the coolant in the sealed system must contain sufficient contraceptives to prevent rust from forming. The coolant must also have a low freezing point in order to cope with all climatic requirements. In addition, it is advisable to use a coolant with a high boiling point

use us higher operating temperatures for the machine and to avoid the possibility of coolant losses Reduce the boil.

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have retained their anti-rust properties and low freezing point, but these coolants can be attacked within a normal vehicle life. A major cause of the onset of the coolant is the chemical effect ergibt- from contact of the coolant with air at high Maschinenbetriebateapeyaturen It is therefore zv / eckmässig, the cooling device of Lxift to be free to the life to increase the coolant "

The volume of liquid coolant changes staring between the lowest anticipated free temperature and the normal operating temperature of the Hasshise ^ Some expansion device may be provided to accommodate the changes in coolant volume. In a conventional downflow cooler, the head container serves as an expansion device. A special expansion tank must be used with a cross-flow collector.

The head tank of a downflow cooler or the expansion tank a cross-flow cooler have sufficient air space, to allow the coolant to expand. The turbulence of the liquid in the expansion device can, however

Air to enter the cooler. So although the system was originally freed of air, the air can immediately enter the system and cause the coolant to attack.

It is therefore the main task of the innovation to provide a sealed To create cooling device that makes the contact of air with the liquid coolant impossible.

A sealed cooler for liquid refrigeration is included an internal combustion engine according to the innovation "exists initially bus a cooling jacket for the machine. Kin heat exchanger is to dissipate the heat generated by the machine. Further are ^ means provided to the liquid Coolant between the heat exchanger and the cooling jacket of the

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of the liquid coolant «The exhausting device consists of a rigid container with an impermeable "flexible wall. The flexible wall is in contact with the old liquid coolant, namely "at the expected minimum vtJLumen of the coolant within the system and is deformable by the coolant when the temperature exceeds the coolant volume increases.

Further features and advantages of the innovation emerge from the following description of exemplary embodiments Innovation based on the drawing, which show:

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Pig. 1 is a schematic representation of an internal combustion engine and the cooling device in a first embodiment according to the innovation,

Pig. 2 shows a partial cross section of a cooler for an internal combustion engine according to another embodiment aer

In the pig. 1 is a liquid-cooled internal combustion engine denoted by 11 ". The engine 11 has a cylinder block 12 and a cylinder head 13, which are provided with cooling jackets are provided in which a suitable liquid coolant circulates. In front of the cylinder block 12 there is one through the crankshaft driven coolant pump H to the liquid coolant to overturn.

A cross-current cooler or heat exchanger 15 is seated in front of the engine 11. The radiator 15 has a central portion 16, from an x ^ hä number Röiir ii ^%! Sliü ^ S

Hip. At each end of the section 16, head containers 17 and 18 are arranged, which are in open communication with the pipes. A generator driven by OCE machine ¥ entilator 19 bewirlrfc an air circulation through the cooling Qitilereii erteil 16, VST dissipate heat generated during operation of the Haschine.

Aa front end of the cylinder head 13 is a connector 21 intended for the coolant outlet. At the top of the pot 17 a connection piece 22 is arranged for the coolant inlet. A flexible hose 23 is at both ends

connected to the terminals 21 and 22 through. Clamps 24 and 25 to direct the coolant flow from the cooling jacket of the machine into the radiator 15. At the bottom of the head container a connection 26 for the coolant outlet is arranged. A "flexible hose 27 connects the outlet port 26 with the

, Inlet side of the coolant pump 14.

. The coolant in the machine 11, the hoses 23 and 27

j and the cooler 15 is "purged of air" when the cooling device

is initially filled. The cooler is completely filled with coolant under normal free temperature. That Coolant expands "at the operating temperature of the machine the end. An expansion device 28 is provided to accommodate changes in volume of the coolant of the machine. the Expansion concern 28 represents the highest point of priority däx ixEra. besxeiii sweet a ^ äi Im container 29, sii one- Sühlaiitel connection 31 * One end of the hose 32 is connected to the connector 31 a terminal 33 connected. The other end of the hose 32 is with a coolant connection 34 at the upper end of the head container 17 connected by a terminal 35.

On one side of the connector 31 extends a "flexible "Wall 36 across the container 29. The cooling device is with sufficient coolant to contact "flexible wall 36 in the unexpanded state", as indicated by line 36a ■ given and that "at the lowest probable free

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Temperature. Is the coolant inside the device through When the machine is running or when the free temperature rises, it expands and deforms the flexible wall 36. It thus appears that the permeable, flexible wall excludes the entry of air into the cooling device at all machine temperatures, although expansion of the Coolant volumes are added.

The internal volume of the container 29 is chosen so that the Deformation of the flexible wall 36, as shown in dashed lines in the drawing with the line 36b, is limited. The cooling device is partially pressurized, so that the boiling point of the coolant is increased. This can be done by having an appropriate inner volume of the Container 29 is selected to the desired pressure increase to achieve »The container 29 can have a pressure relief valve 37 on the coolant side of the flexible wall 36 have. The pressure relief valve can be screwed onto a connector 38 of the container 29 be to a decrease when pulling the cooling system 2U enable. It has a movable valve part 39 which is pressed into the closed position by a helical spring 41. The spring tension is selected so that the valve 39 is lifted off when the coolant pressure exceeds a certain value. In most normal operating conditions the Masehl'ne is the valve 39 is closed soin.

The embodiment described uses a cross-flow

cooler and requires a special expansion device. 3of that If a downflow cooler is used, it is possible to use the expansion device to connect to the upper head container of the cooler. A same version is in the 3? Ig. 2 shown. The machine and the lower part of the cooler have not been shown as these parts are of the usual design The machine and the coolant inlet and outlet can be the same as in Pig. 1. The inlet of the coolant in the machine can be connected to the lower head container of the cooler by a flexible hose in a manner known per se be.

In FIG. 2, a flow cooler is denoted by 51. This Cooler 51 ″ has a number of through-flow tubes 52, which are formed by heat exchange fins 53 are enclosed. The upper head container 54 is with its lower side in open communication with the Pipes 52. The inlet connection 55 for the coolant of the cooler 51 flows liquid coolant over a flexible one Hose 56, which is connected to the machine. A clamp 57 provides a tight connection between the hose 56 and the inlet stutz-en 55.

Transversely through the head container 54 extends a flexible, impermeable wall 58. As in the embodiment already described become the liquid in the cooler 51 -, the machine and purge the coolant hoses of air if that Cooling system is initially filled. The flexible wall 58 is in place

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"at the lowest possible free temperature through the head container 54 in contact with the coolant. Of the Inlet port 55 is below wall 58 ″ at this temperature.

If the coolant temperature rises, the increase in volume is deformed of the coolant the "flexible wall 58. The inner The volume of the head container 54 is sufficient to accommodate the increase in volume "at normal operating temperatures of the machine. Here, the" flexible wall 58 is in contact with the upper surface of the head container 54 is burned, as in the Mg. 2 shown in dashed lines. Optionally, the system can be pressurized by reducing the volume of the head container 54 set v / earth.

A device can be provided to enable the coolant to be filled into the system and to allow transfer pressure. to drain. This device consists of a connection piece 59 which extends from a point above the surface of the head container 54 to the head container below the flexible wall 58. At the inlet of the connection piece 59 a filler cap provided with an overpressure valve 61 is provided Fig. 1 can have _s

Many modifications are possible without going beyond the scope of the The idea of innovation to emerge.

Claims (4)

Security talks 1. Sealed cooling device for internal combustion engines, "consisting of from a cooling jacket of the machine and a heat exchanger connected to it, as well as an expansion vessel to accommodate the change in volume of the coolant, characterized in that the expansion device consists of a rigid container with a flexible wall (36, 58), which "with the smallest amount of cooling agent Touches coolant and from this at durci. feaperatur effected Increase in coolant volume is deformed * 2. Cooling device according to claim 1, characterized in that the flexible wall (36, 58) is impermeable to air, so that no air can enter the coolant system through them. 3. Cooling device according to claim 1, characterized in that the volume of the rigid container (29, 54) is not greater is than the increase in volume of the liquid coolant when heating from the lowest ambient temperature to the normal operating temperature of the cooling system. 4. Cooling device according to claim 1-3, wherein the heat exchanger has a head container characterized in that the flexible wall (58) traverses the head container he (54) runs. 1 Q Q 7 Q Γο.Μ-η ,, ΐΓΚ .. "^ elch" n Un.erio,. * Taftnden * h In the