DE19755042A1 - Control device for cooling circuit of motor vehicle IC engine - Google Patents

Abstract

The device has an actuator element (2) for opening and closing a short circuit line (12) in the coolant circuit (8) and a control element (8) which acts upon the actuator element. The control element has a pressure membrane (3) which communicates on one side with the coolant circuit via a pressure connection and which is adjustable between two switching positions depending on the pressure in the coolant circuit. A change in the switching position can be transferred to the actuator element via a transfer element (4). An Independent claim is also included for a method for controlling the coolant temperature of the coolant circuit.

Description

The invention relates to an actuating device for the Cooling circuit of an internal combustion engine and a method for Regulation of the coolant temperature according to the generic term of the Claim 1 or 5.

From DE 44 38 552 C1 it is known in the cooling circuit to provide a short-circuit line to an internal combustion engine, shut off or released via a switching flap can be. Hot water flows through the short-circuit line in the short circuit to the engine block of the internal combustion engine led to accelerate on a cold engine Warm operating temperature. When the engine is warm the short-circuit line is blocked and it is from one Cooler cold water coming to the cylinder head Internal combustion engine led. The cooling water is by means of a coolant pump in the cooling circuit.

The control flap is controlled via a temperature Expansion element that under the influence of Coolant temperature undergoes a change in length and one Change in the switching flap position causes. Parallel to Expansion element is a return spring arranged counteracts expansion of the expansion element. Around Space for the return spring and the expansion element too create is a branch from the short-circuit line Side channel provided, which is covered by a cover plate Short-circuit line is disconnected. For one  reliable operation, the coolant must be in the Inflow side channel, so that a temperature transfer from the coolant to the expansion element is possible; this can cause flow eddies.

The invention addresses the problem that generic actuating device or the generic Train the process so that load or Depending on the temperature, the short-circuit line with little effort can be opened or closed with a high level of functional reliability can.

This problem is inventively with the features of Claims 1 and 5 solved.

The control element of the actuator becomes independent of the coolant temperature only via the pressure in the Cooling circuit operated. The temperature independent Control element can be outside the coolant lines be arranged; the cooling circuit and the control element spatially decoupled. Transfer of pressure from Cooling circuit to the control element takes place with the help of a outside the coolant line Pressure connection. The coolant flow is through the Control element and the pressure connection is not hindered. The Control element, which is designed as a pressure diaphragm changes under the influence of a change in pressure in the Coolant line its switching position. The switching movement the pressure membrane is made with the help of a transmission link transferred to the actuator. The actuator is located depending on the switching position of the pressure diaphragm either in Open position in which the flow cross section of the Short circuit line is enabled, or in  Closed position in which the short-circuit line is shut off is, or in an intermediate position.

The pressure membrane is inexpensive to carry out and can be light be integrated into the actuator.

According to the inventive method, the pressure is as System parameters in the cooling circuit as the manipulated variable of the Control element used. Depending on the pressure level in the The cooling circuit takes the control element over which the free Flow cross-section set in the short-circuit line will enter different positions and enter the Short-circuit line free or blocked. The control reacts more directly and via the pressure-dependent control element faster than conventional temperature-dependent Thermostatic valves, so that a more precise setting is possible.

The temperature is expediently regulated in Dependency of the speed of the coolant pump over which the Coolant is circulated in the cooling circuit. About the The speed depends on the pressure in the cooling circuit. At low speed, for example after the start of the engine or for small loads is the Flow rate of the coolant in the cooling circuit is low. Accordingly, there is only one in the cooling circuit low pressure on the pressure connection to the Pressure membrane is passed. The pressure membrane is located below an adjustable speed limit - and associated with it below a certain one Pressure value - in the switching position that the Corresponds to the open position of the control element; in this Position can coolant through the short circuit line stream. At a higher speed, the pressure in the  Coolant line on and the pressure membrane takes one other switch position. By means of the transmission link will change the switching position on the actuator transferred that accordingly in its closed position is transferred. The change in position of the actuator can continuously or approximately suddenly respectively.

In a preferred embodiment, both sides of the Pressure membrane with different high pressures acted upon. In particular, the pressure from the Coolant line immediately before and after the Tapped coolant pump and on each side of the Pressure membrane directed. In this version, the Switching position of the pressure diaphragm by the differential pressure determined between the inlet and outlet of the coolant pump.

Further advantages and practical embodiments are the further claims, the description of the figures and Drawing can be seen in the an embodiment is shown schematically.

In the cooling circuit 8 shown in the figure, a coolant, in particular water, is circulated via a coolant pump 7 in order to cool the warm engine during operation. The coolant is sucked via the suction side 7b of the pump 7 from a suction line. 9 The coolant flows via the pressure side 7 a of the pump into a pressure line 10 . An actuating element 2 is arranged in the pressure line 10 , which together with a control element 3 , a transmission element 4 and pressure connections 5 and 6 forms an actuating device 1 . Behind the control element 2 , the pressure line branches into a pressure line section 11 and a short-circuit line 12 . The control element 2 , which is designed, for example, as a 2-way valve, is switched when the engine is warm so that the coolant is conducted into the pressure line section 11 , ie, in this switch position, the control element 2 is in a closed position which blocks the short-circuit line 12 . The pressure line section 11 , which is part of the main circuit of the coolant, leads to a cooler, not shown. After passing through the cooler, the coolant flows through the engine and cools it. The coolant is then returned to the return line or suction line 9 .

If necessary, the coolant pump 7 is placed directly in front of the engine in the cooling circuit so that coolant is reliably flowed through the engine block.

In the open position of the control element 2 , in which the short-circuit line 12 is activated, the coolant flows directly bypassing the cooler via the short-circuit line 12 to the engine block. The uncooled coolant is used to heat the engine, for example after a cold start or with small loads, in order to bring it up to operating temperature more quickly.

The switching state of the control element 2 is changed via the control element 3 , which is designed as a pressure membrane. The pressure membrane 3 is acted upon by pressure connections 5 , 6 with the system pressure prevailing in the cooling circuit 8 . Via the pressure connection 5 , the pressure p ₁ from the pressure line 10 is present on one side 3 a of the pressure membrane 3 . The pressure p _{1 of} the cooling circuit 8 is expediently tapped off directly behind the coolant pump 7 on the pressure side 7 a and passed to the side 3 a of the pressure membrane 3 . The other side 3 b of the pressure membrane communicates via the pressure connection 6 with the suction side 7 b of the pump 7 ; the pressure p _{2 is present} on this side, which is less than the pressure p ₁ on the pressure side 7 a. The position of the pressure membrane 3 is determined by the differential pressure Δp between the two sides 3 a, 3 b of the pressure membrane 3 .

According to another advantageous embodiment, the side 3b of the pressure membrane 3 is pressurized with atmospheric pressure via the pressure connection 6 '.

Depending on the preload of the pressure membrane and the level of the differential pressure Δp between the two sides 3 a, b, the pressure membrane assumes different switching positions which are transmitted to the actuating element 2 via the transmission element 4 . A change in the pressure difference Δp causes a change in the switching position of the pressure membrane, which is passed on to the control element 2 via the transmission element 4 . It is thereby possible to set the switching state of the control element 2 as a function of the pressure p in the cooling circuit 8 . At a low pressure p, which occurs when there is little pumping by the coolant pump, the actuating element 2 is in the open position, in which the short-circuit line 12 is activated. At a higher pressure p, which occurs with a greater delivery, the actuating element 2 is in the closed position, in which the short-circuit line 12 is blocked and the coolant circulates exclusively in the main circuit through the pressure line section 11 . The position of the control element 2 is thus dependent on the pressure in the cooling circuit and indirectly on the delivered coolant flow, which is a function of the pump speed.

Claims (6)

1. Setting device for the cooling circuit of an internal combustion engine, with an adjusting element ( 2 ) for opening and closing a short-circuit line ( 12 ) in the cooling circuit ( 8 ), and with a control element ( 2 ) acting on the control element ( 3 ), characterized in that the control element ( 3 ) is a pressure membrane ( 3 ), one side ( 3 a) of which communicates with the cooling circuit ( 8 ) via a pressure connection ( 5 ) and which is adjustable between two switching positions depending on the pressure (p ₁ ) in the cooling circuit ( 8 ) A change in the switching position can be transmitted to the actuating element ( 2 ) by means of a transmission element ( 4 ). 2. Adjusting device according to claim 1, characterized in that the other side ( 3 b) of the pressure membrane ( 3 ) via a further pressure connection ( 6 ) with a different pressure (p ₂ ) is applied. 3. Adjusting device according to claim 1 or 2, characterized in that the two pressure connections ( 5 , 6 ) with the pressure side ( 7 a) and with the suction side ( 7 b) of a coolant pump ( 7 ) which is arranged in the cooling circuit ( 8 ) , are connected. 4. Adjusting device according to claim 1 or 2, characterized in that the further pressure connection ( 6 ) is connected to the atmosphere. 5. A method for controlling the coolant temperature in the cooling circuit of an internal combustion engine, in particular for operating the actuating device according to one of claims 1 to 4, wherein the coolant in the cooling circuit ( 8 ) is circulated and passed below a system limit value (p _g ) through a short-circuit line ( 12 ) whose opening cross-section is adjustable via an adjusting element ( 2 ), characterized in that the pressure (p) in the cooling circuit ( 8 ) is used as the manipulated variable of the adjusting element ( 2 ). 6. The method according to claim 5, characterized in that the temperature control takes place exclusively via the speed (s) of a coolant pump ( 7 ), the short-circuit line ( 12 ) being open in a speed range below an adjustable limit value (n _g ).