1. Field of the Invention
The invention relates to a coolant circuit of a motor vehicle, which comprises both a coolant pump and a retarder, the working medium of the retarder being the coolant.
2. Description of the Related Art
A hydraulic oil has been conventionally used as the working medium of a retarder in the driveline of a motor vehicle. On account of the heat produced in the braking mode, the hydraulic oil had to be cooled. Provided for this purpose was, as a rule, an oil-water heat exchanger as interface between the cooling circuit and the working medium circuit of the retarder, by means of which the requisite quantity of heat was dissipated from the retarder circuit into the cooling circuit of the vehicle.
In recent times, retarders have also become known that are arranged directly in the conventional coolant circuit of the vehicle and whose working medium is the coolant of the cooling circuit. The provision of such retarders in the cooling circuit can result in an increase in the total flow resistance or the resistance of flow of the coolant in the cooling circuit.
Such an increase in the total flow resistance takes place to a substantial extent also in the case of so-called oil retarders on account of the additional components in the coolant circuit, such as, for example, the oil-water heat exchanger. This increase in the flow resistance has drawbacks. Accordingly, it is not possible to employ any conventionally dimensioned coolant pump, such as those finding use in cooling circuits without retarders. Instead, a higher power coolant pump must be be used.
More power is required to drive the higher power coolant pump and this leads to an increased fuel consumption of the motor vehicle. This is of especially great consequence due to the fact that this increased power input of the coolant pump
The invention is based on the problem of creating a coolant circuit that has a coolant pump and a retarder and that is improved over the prior art. In particular, it should be possible to use a coolant pump that does not require a higher power input or power output than coolant pumps in cooling circuits without retarders.
The problem of the invention is solved by the features of claim 1. The subclaims describe especially advantageous constructions.
The invention and its advantages over the prior art will be described below on the basis of the figures,
Shown in detail are the following:
a,
5
b a sectional depiction through a reversing valve;
Evident in
The flow of cooling medium, particularly the flow of cooling water that is required for transporting energy is moved by the pump 1, via the engine 5, the water-carrying part of the oil-water heat exchanger 12, via the thermostat 15, and via the water-air radiator 16 to the intake side of the pump 1. The flow resistances that are present in the circuit need to be overcome by the pump 1 during this circulation; that is, the power input or power output of the pump must be sufficiently high that the pressure of the working medium at the pump outlet 1.1 due to the pressure level produced by the pump lies so far above the pressure level on the intake side that an appropriate circulating flow is established throughout the entire coolant circuit.
Additional resistances in the coolant circuit reduce and impede the circulating flow of cooling water and thus the quantity of heat that can be effectively transferred or else, for the same flow of cooling water, necessitate a more powerful pump, which entails an increased power input. Such an increased power input leads to an increase in fuel consumption, which is not desired.
Such an additional resistance is created, for example, by the oil-water heat exchanger 12. When one considers that the retarder is required for braking during only about 10 percent of the time the vehicle is being employed, the remaining 90 percent of the time the vehicle is being employed means a pump operation with unnecessarily high power input.
As can be seen, the retarder 2 is arranged directly in the coolant circuit and can be bypassed by way of the bypass section 4. Arranged in the flow direction upstream of the retarder 2 is a reversing valve 3 for controlling the flow—either through the retarder 2 or through the bypass 4.
The coolant pump 1, arranged upstream of the reversing valve 3, corresponds, in terms of its power range, to a coolant pump of a coolant circuit without a directly incorporated retarder or without an incorporated oil-water heat exchanger for a separate retarder circuit, such as is depicted in
In the braking mode of the retarder, the flow resistance between the pump outlet 1.1 and a position in the central ring of the retarder 2 is laid out in such a way that it lies below the previously described total flow resistance of the coolant circuit in the non-braking mode. Accordingly, the power of the pump 1 is adequate to make available an adequate superimposed pressure for the retarder 2, so that the latter takes over the remaining pumping work for circulating the coolant in the coolant circuit 10 up to the intake side of the pump 1. One aspect of the embodiment depicted may thus be seen in the fact that the pump 1 overcomes only the resistance path from the coolant outlet 1.1 of the pump up to the retarder 2, that is, more precisely stated, up to the central ring of the retarder 2. The flow resistance in the remaining coolant circuit is overcome by the connected retarder. This is readily possible if one considers that the coolant pump has a power range that is in a ratio of 1:100 in comparison to the power range of the retarder in terms of possible pumping capacity. For example, the pump has a power of approximately 6 kilowatts and the retarder has a power range of 500 to 600 kilowatts.
Due to the fact that, in accordance with the invention, the flow resistance that is to be overcome by the coolant pump 1 in the braking mode is lower than in the non-braking mode, an increased circulated quantity of cooling medium is established. This is especially of advantage in the braking mode of the retarder in order to increase the thermal availability of such a braking system and thus to expand in a comparable manner the possible wear-free braking mode, which, in turn, leads to a relief of the friction brakes provided in the vehicle. Due to the fact that the retarder is arranged in the flow direction upstream of the engine 5 that is being cooled, it is possible to keep especially low the flow resistance that is to be overcome by the coolant pump, on the one hand, which, in turn, increases the throughput at the same speed, and, on the other hand, the working medium in the retarder has a relatively low temperature.
Shown in
The advantage of this embodiment is that the coolant heated in the retarder is cooled directly afterwards in the radiator 16. When the retarder is constructed appropriately, it is possible to permit coolant temperatures that lie above the permitted coolant inlet temperatures at the engine 5.
In the embodiment shown according to
The arrangement according to
Depicted in
In this embodiment also the carrying of the flow from the outlet 1.1 of the coolant pump 1 up to the central ring of the retarder 2 is designed in such a way that the flow resistance of this path is lower than the flow resistance in the non-braking mode of the entire coolant circuit 10.
In all of the embodiments shown, it may be especially advantageous to make an adaptation of the flow resistance between the pump outlet 1.1 and the central ring of the retarder 2 by way of a predetermined number of holes in the filling system of the retarder. The number and/or the size of the holes or of the respective filling cross sections are chosen advantageously according to the respective resistance characteristics of the vehicle cooling system used.
In the following, several constructions for adjusting an especially low flow resistance are presented.
a and 5b show schematically an advantageous embodiment of a reversing valve 3. The reversing valve 3 shown is constructed as a rotary slide valve and has an inlet 3.1, a first outlet 3.2, and a second outlet 3.3. Cooling medium is introduced via the inlet 3.1 at least indirectly by the coolant pump 1. Via an outlet—for example, the outlet 3.2—coolant is diverted into the bypass 4 around the retarder and, via another outlet—for example, the outlet 3.3—to the retarder 2.
Furthermore, the reversing valve 3 has a cylindrical valve piston 3.4, which can rotate around its longitudinal axis. The cylindrical valve piston has radial holes, namely, an outlet hole 3.5 and an inlet hole 3.6. The outlet hole 3.5 typically has a cylindrical construction, whereas the inlet hole 3.6 has a conically tapering construction or a funnel-shaped construction. One, both, or several holes can obviously also have other shapes in terms of their cross section—for example, the shape of an oblong hole. Rotation of the cylindrical valve piston 3.4 around its longitudinal axis connects the inlet 3.1 with one of the two outlets 3.2 and 3.3 in a targeted manner.
For the above-described connections of the outlets 3.2 and 3.3, the state of the non-braking mode of the retarder is shown in
The conically tapering inlet hole 3.6 has an inlet opening on the circumference of the valve piston 3.4 that is dimensioned in such a way that, regardless of the position of the valve piston 3.4—that is, regardless of whether the latter connects the inlet 3.1 to the outlet 3.2 in a flow-carrying manner or whether it connects the inlet 3.1 to the outlet 3.3—the inlet opening of the inlet hole 3.6 completely surrounds the flow cross section of the inlet 3.1.
The design of the rotary slide valve, which is shown, results in a solution that is extremely favorable in terms of flow and offers low resistance.
The stator 2.2 has a plurality of stator blades 2.7. A predetermined number of the stator blades 2.7 are provided with a hole 2.3 for introducing the working medium into the working chamber of the retarder 2.4. In the embodiment shown, every second stator blade 2.7 has such a hole 2.3. In an extreme case, each stator blade would have a corresponding hole. Stator blades with holes are also referred to as filling blades.
The inlet into the central ring region of the retarder corresponds to the stator outlet, that is, to the discharge of the working medium out of the holes 2.3 into the filling blades.
The working medium flows on the inlet side of the working medium, 2.5, via a central hole 2.8, over the entire circumference of the stator 2.2. In order to achieve an especially uniform distribution of the incoming flow over the entire circumference, a number of guide elements 2.6, particularly in the form of ribs, are provided on the stator inlet side.
The uniform distribution of the working medium, which enters through the central hole 2.8, over the entire stator circumference and thus the uniform distribution onto all filling blades, particularly onto every stator blade or every second stator blade, results in an especially low-resistance flow up to the central ring of the retarder, that is, up to the stator outlet.
However, it is not necessary to construct the ring channel in a rotationally symmetric manner with respect to the center line. Deviating shapes—on account of, for example, the construction space available on the transmission—can also be constructed.
Provided in the stator housing 2.10 radially outside of the inlet channel 2.9, which is constructed as a ring-shaped channel, is an outlet channel 2.11, which is also constructed as a ring-shaped channel, in order to carry off working medium from the retarder working chamber via a retarder outlet.
FIGS. 8 to 11 show further measures in the region of the filling blades that decrease the flow resistance. Thus, according to
Finally,
Number | Date | Country | Kind |
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103 32 907.2 | Jul 2003 | DE | national |
This application claims priority in PCT International Application No. PCT/EP2004/007546, filed Jul. 9, 2004, and German Application No. DE 103 32 907.2-16 filed Jul. 19, 2003, the contents of which are incorporated herein by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP04/07546 | 7/9/2004 | WO | 7/6/2006 |