JPH0510191A - Engine controller - Google Patents

Abstract

PURPOSE:To form each of main parts of control into commonness as well as to make them easily adaptable to auxiliaries in a way of changing an encoding data part even if these auxiliaries are varied with one another by controlling each of load elements so as not to produce any rotational variations, on the basis of drive mode information encoding a drive mode at each load element. CONSTITUTION:In an engine controller where an ISC unit 1, an EGI unit 2 and an ESA unit 3 controlling ignition operation are connected to a main control unit 4, various auxiliaries, for example, a power steering unit 6, an alternator unit 7, a light control unit 8, an air pump unit 9 and an AT control unit 10 are connected to this main control unit 4 as well. In this case, characteristics of each auxiliary are divided into plural factors and extracted separately, and an evaluation function made up of evaluating a degree as to each factor with bivalent data is stored in the main control unit 4 in advance. Then, such a controlled system as negating any variation in driving force at the time of operation of one auxiliary is made so as to be selected as a parameter of the evaluation function.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an engine control device, and more particularly to an engine control device having a plurality of accessories driven by engine output.

[0002]

2. Description of the Related Art Generally, a vehicle is equipped with a plurality of auxiliary components driven by an engine, such as a compressor of an air conditioner (hereinafter referred to as an air conditioner), a pump for power steering, and an alternator for power generation. When the operating states of these accessories change, the engine output fluctuates, the net drive torque transmitted to the drive system fluctuates accordingly, and the engine rotation also fluctuates.

In order to suppress such torque fluctuations associated with changes in the operating state of the engine driven auxiliary machine, ignition timing and fuel are conventionally controlled so that engine rotation does not occur in accordance with the engine speed representing engine output. It is general to feedback control the supply amount. Further, there is a case where the torque fluctuation is absorbed between the auxiliary machines by changing the operating state of the auxiliary machines.

[0004]

However, when the engine output is directly controlled as in the former case, the fuel consumption is sacrificed even if the engine rotation does not fluctuate, and the torque fluctuation cannot be absorbed completely. There may be fluctuations.
In addition, even if torque fluctuations are absorbed between auxiliaries like the latter, the control logic is not constant in the current situation where the installation status and characteristics of auxiliaries vary from model to model, and a dedicated control program is prepared for each model. The fact is that we have to do it.

The present invention addresses the above situation in an engine having a plurality of accessories driven by engine output, and is not affected by the installation conditions or characteristics of the accessories,
An object of the present invention is to appropriately suppress a change in driving force due to a change in an operating state of an auxiliary machine.

[0006]

That is, the engine control device according to the invention of claim 1 of the present application (hereinafter referred to as the first invention) is a load element in an engine having a plurality of load elements operating at engine output. The driving mode information storing means for storing the driving mode information in which each driving mode is coded and the driving state signal of the other load element are detected when the driving request signal for operating the load element is input. A load element search means for searching for a load element indicating a drive form that cancels the change in the driving force when the load element indicated by the drive request signal is activated, based on the drive form information stored in the storage means, and It is characterized in that a load element control means for controlling the load element and the load element having a drive request so as to prevent the engine output from varying in rotation is provided.

The invention of claim 2 of the present application (hereinafter, referred to as the second
In the engine having a plurality of load elements that operate at the engine output, the control device for an engine according to the invention) stores drive form information in which drive form information in which the drive form for each load element is divided into a plurality of factors and coded is stored. When the storage means and the drive request signal for operating the load element are input, the operating states of the other load elements are detected to cancel the change in the driving force when the load element indicated by the drive request signal is operated. When there are a plurality of corresponding load elements, the load element search means searches the load elements indicating such a drive form based on the drive form information stored in the storage means, and when there are a plurality of applicable load elements, a predetermined factor determined for each factor is set. The load element selection means for selecting the load elements according to the priority order and the selected load element and the load element with a drive request are controlled so that rotation fluctuation does not occur in the engine output. Characterized by providing a load element control means for.

In the engine control device according to the invention of claim 3 of the present application (hereinafter referred to as the third invention), in an engine having a plurality of load elements operating at engine output, a plurality of drive modes for each load element are provided. The drive mode information storage means for storing the drive mode information coded according to the factors and the drive state signal of the other load element are detected when the drive request signal for operating the load element is input. A load element search means for searching for a load element indicating a drive form that cancels a change in the driving force when the load element indicated by the request signal operates based on the drive form information stored in the storage means, and a corresponding load There are multiple elements,
When the factors of the respective load elements are common, the load element selecting means for selecting a load element having a small arithmetic mean of the numerical values indicating the predetermined priority order defined for each factor, and the selected load element and the load requested to be driven. And load element control means for controlling the elements so that the engine output does not fluctuate in rotation.

Further, in the engine control device according to the invention of claim 4 of the present application (hereinafter referred to as the fourth invention), in the engine having a plurality of load elements operating at the engine output, the drive mode for each load element is coded. Drive form information storage means that stores the converted drive form information, and when the drive request signal for operating the load element is input, the operating state of another load element is detected and the load indicated by the drive request signal is detected. Load element search means for searching for a load element indicating a drive form that cancels a change in driving force when the element operates, based on the drive form information stored in the storage means; A load element control means that controls a certain load element so that the engine output does not fluctuate in rotation, and if there is no corresponding load element, the operation of the load element that requires driving is performed. Wherein the rotational fluctuation in the engine output at is provided with an engine output adjusting means for adjusting the engine output so as not to cause.

The invention of claim 5 of the present application (hereinafter referred to as the fifth
In an engine having a plurality of load elements that operate at engine output, a control device for an engine according to the invention) includes a drive form information storage unit that stores drive form information that encodes a drive form for each load element, and a load. When a drive request signal for actuating an element is input, the driving state is detected such that the operating state of another load element is detected and the change in the driving force when the load element indicated by the drive request signal is cancelled. The load element search means for searching the load element shown on the basis of the drive form information stored in the storage means, and the searched load element and the load element for which a drive is requested are controlled so that the engine output does not fluctuate in rotation. When the load element control means and the corresponding load element do not exist, the ignition timing is retarded in advance, and the ignition timing is advanced when the load element that is requested to drive is activated. Characterized by providing an ignition timing control means for.

When the driving form of the load element is coded, it may be coded by dividing it into at least a plurality of factors of torque change speed, torque change amount, timing operability, and torque variability.

[0012]

According to the above configuration, since the load element is controlled based on the drive form information in which the drive form of each load element is coded, the main part of the control is made common. Therefore, even if the installation conditions and characteristics of the auxiliary machinery are different, it is only necessary to change only the data part to be encoded.

In particular, according to the second and third aspects of the invention, when the change of the driving force due to the change of the load is suppressed by the control of the load element, the minimum required drive state of the load element is changed. Well, this allows the sacrifice of load elements to be minimized.

[0014]

EXAMPLES Examples of the present invention will be described below.

As shown in FIG. 1, an engine control system according to this embodiment includes an idle speed control unit (hereinafter referred to as an ISC unit) 1 for controlling the amount of air that bypasses a throttle valve (not shown). An electronic gasoline injection unit (hereinafter referred to as an EGI unit) 2 for controlling a fuel supply amount and an electronic ignition advance unit (hereinafter referred to as an ESA unit) 3 for controlling ignition timing and energization time are provided. , Each of these units 1 to 3 and the main control unit 4
Various signals are transmitted and received between and.

In this embodiment, the air conditioner unit 5 for controlling the air conditioner system and the power steering unit for controlling the power steering system (hereinafter referred to as P
S unit) 6, an alternator unit 7 that controls an alternator system, a light control unit 8 that controls lights, an air pump unit 9 that controls the operation of an air pump for supplying air to a catalyst (not shown), A for controlling the operation of an automatic transmission (not shown)
The T control unit 10 is provided, and the units 5 to 10 are also configured to exchange signals with the main control unit 4.

Further, in this embodiment, the characteristics of the individual auxiliary machines, that is, the load elements are characterized by torque change speed (A), torque change amount (B), timing operability (C), controllability (D), The torque variability (E) and the torque variability (F) are divided into six factors (A to F) and extracted, and the degree of each factor (A to F) is set to 1 or 0.
It is evaluated by binary data. Taking an air conditioner as an example, as shown in Table 1, the torque change speed is slow (A =
0), the amount of torque change is large (B = 1), the timing can be operated (C = 1), the operation cannot be performed when the driver turns off the switch (D = 0), and the torque is continuously variable. Since (E = 1), the direction of torque changes in the negative direction during operation (F = 0), so the evaluation function that characterizes it is f (0,1,1,0,1,0). Become. Since this evaluation function is determined based on the general property of the air conditioner, it has a data structure that does not depend on the characteristics of the air conditioner.

[0018]

[Table 1] Similarly, evaluation functions for power steering and other load elements are obtained, and these evaluation functions are stored in the main control unit 4 in the state of a digital map for each load element.

In this embodiment, the factors (A to F) are prioritized in descending order. For example, regarding factor (A), the air pump, the power steering, the lights, etc. Since the torque change speed becomes slower in the order of the alternator, the numerical value indicating the priority order of the factor (A) is ○ in Table 1 above.
As indicated by the numbers in the figure, the air pump has 1, the power steering has 2, the lights have 3, and the alternator has 4.
Then, for air conditioners and automatic transmissions that have a slow torque change speed, the numerical value indicating the priority order is set to, for example, infinity.

In this embodiment, the engine control element is also characterized by the torque change speed (A),
The torque variation (B), the timing operability (C), the controllability (D), the torque variability (E), and the torque variability (F) are divided into six factors (A to F) and extracted. The degree of the factors (A to F) is evaluated by binary data of 1 or 0. Taking ISC as an example, as shown in Table 2 below, the torque change speed is slow (A = 0), the torque change amount is large (B = 1), and the timing operation is possible (C = 1). , The control does not depend on the driver (D = 1), there is continuous torque variability (E = 1), and the direction of the torque changes in the positive direction during operation (F = 1). The evaluation function indicating is f (0,1,1,1,1,1). Even in this case, since the evaluation function is determined based on the general property of ISC, it has a data structure that does not depend on the individual property of ISC.

[0021]

[Table 2] Similarly, evaluation functions for EGI and ESA are obtained, and these evaluation functions are stored in the main control unit 4 in a digital map state for each engine control element.

Also in this case, each factor (A
~ F) are prioritized in descending order of magnitude. For example, regarding factor (A), E
Since the torque change speed becomes slower in the order of SA, EGI, and ISC, the numerical value indicating the priority order for factor (A) is as follows:
Is 2 and ISC is 3.

Next, the control operation performed by the main control unit 4 will be described as follows in accordance with the flowchart of FIG.

First, the main control unit 4 performs step S
In 1, it is determined whether the drive request signal is output.
When it is determined to be S, the load state of each unit is read in step S2, and the torque fluctuation when the load element having the drive request is activated from the evaluation function stored in the map is canceled in step S3. When a load element indicating the drive form is searched and it is determined that the corresponding load element exists in step S4, the process proceeds to step S5, it is determined whether or not there are a plurality of corresponding load elements, and when it is determined to be NO. Step S6 is skipped and the process proceeds to step S7, in which predetermined auxiliary equipment control is performed to control the load element having the drive request and the selected load element so that the engine output does not fluctuate in rotation.

On the other hand, when the main control unit 4 determines in step S5 that there are a plurality of drivable load elements, it proceeds to step S6 and performs a predetermined optimum load element selection process.

That is, for example, f (1, ×, ×, ×, ×,
It is assumed that the evaluation function indicating the code form of 0) is searched.
In addition, x in () indicates that either 0 or 1 may be used.

Then, as shown in Table 1 above, the power steering, the alternator, the lights, and the air pump correspond to the above evaluation function. Therefore, the main control unit 4 preferentially selects the air pump unit 9 according to the priority assigned to each load element. When the operation amount is insufficient with the air pump unit 9 alone, the PS unit 6 having the next priority is selected, and the priority is small until the driving torque consumed when the load element to be controlled is driven is compensated. The load elements will be sequentially selected.

When an evaluation function involving a plurality of factors such as f (1,1, ×, ×, ×, 0) is searched,
As shown in Table 1 above, the power steering and the alternator meet the above conditions. In this case, the smaller of the average values of the priorities of the two is selected. That is, for power steering, the priorities of the factors (A, E) are 2 and 3, respectively, so the addition average value is 5/2, and for the alternator, the priorities of the factors (A, B) are. Since 4 and 2, the addition average value becomes 6/2 and the power steering is selected.

If the main control unit 4 determines in step S4 that there is no drivable load element, the main control unit 4 proceeds to step S8 to select an optimum engine control element, and then executes predetermined engine control in step S9. To do.

Next, the operation of the present embodiment will be described by dividing it into cases.

That is, for example, as shown in FIG. 3, when the control element x ₁ having a good timing operability whose evaluation function is represented by f (×, ×, 1, ×, ×, 0) is turned on, f
It is assumed that the control element x ₂ indicated by (×, 1, ×, ×, 1,0) is in the OFF state. In that case, as shown in the time chart of the figure, the control element x ₂ is controlled stepwise, and the control element x ₁ is turned on at a predetermined timing. Therefore, the engine output does not change excessively. When there are a plurality of control elements that satisfy the above conditions, the one with the highest priority is selected according to the predetermined selection rule as described above.

Further, as shown in FIG. 4, the evaluation function is f
When the control element x ₁ having a slow torque change speed represented by (0, ×, ×, ×, ×, 0) is turned on, f (×, 1,
It is assumed that the control element x ₂ indicated by x, 1, 1, 0) is in the ON state. In that case, as shown in the time chart of the figure, the control element x ₂ is turned off in synchronization with the ON operation of the control element x ₁ . Therefore, even in this case, the engine output does not change excessively.

Then, as shown in FIG. 5, the evaluation function is f
When the torque change speed indicated by (1, ×, 1, ×, ×, 0) is fast and the control element x ₁ having good timing operability is turned on, f (×, 1, ×, 1, 1, 0 It is assumed that the control element x ₂ indicated by () is in the ON state. In that case,
As shown in the time chart of the figure, the control element x
_The control element x ₁ is turned on after a delay of the OFF operation of ₂ . Therefore, even in this case, the engine output does not change excessively.

On the other hand, as shown in FIG. 6, the evaluation function is f
It is assumed that there is no load element that can reduce the drive when the control element x ₁ whose torque change speed indicated by (1, ×, 0, ×, 0,0) is fast and the drive torque cannot change is turned on. . In that case, an engine control element that cancels the change in the driving force when the control element x ₁ is turned on is searched, and as a result, the evaluation function is f (×, 1, ×,
A control element x ₂ (for example, ISC unit 1) indicated by ×, 1, 1) and an evaluation function f (1, ×, ×, ×,
It is assumed that the control element x ₃ (for example, ESA unit 3) indicated by x, 1) is searched. In that case, as shown in the time chart of the figure, the control element x ₁ is turned on.
Fast control element x ₃ is O in synchronization with the operation of the torque change rate
N is done. Then, a control element x _{2 with} a large torque change amount
The control amount of the control element x ₃ is reduced as the control amount of is increased. Therefore, the control element x ₁ is turned on.
Sudden torque changes during operation are suppressed and the driving force does not drop significantly.

Further, as shown in FIG. 7, the evaluation function is f
It is assumed that there is no load element capable of reducing the drive when the control element x ₁ capable of delaying the timing indicated by (x, x, 1, 1, x, 0) is turned on. In that case, an engine control element that cancels the change in the driving force when the control element x ₁ is turned on is searched, and as a result, the evaluation function is represented by f (1, ×, ×, ×, ×, 1). It is assumed that the control element x ₂ (for example, ESA unit 3) to be searched is retrieved. In that case, as shown in the time chart of the figure, the ignition timing is retarded by the operation of the control element x _{2 having} a fast torque change speed, that is, the ESA unit 3, prior to the ON operation of the control element x _1. . Then, the ignition timing is advanced at once in synchronization with the ON operation of the control element x ₁ .

By retarding the ignition timing prior to the operation of the load element in this manner, there is an advantage that the output fluctuation when the load element operates is reduced.

Incidentally, in order to compensate the output reduction due to the retard of the ignition timing, a control element having a large torque change amount, for example, the ISC unit 1 may be operated.

Further, as shown in FIG. 8, the evaluation function is f
It is assumed that there is no load element capable of reducing the drive when the control element x ₁ capable of delaying the timing indicated by (x, 1, x, 1, 1, 0) is turned on. In that case, an engine control element that cancels the change in the driving force when the control element x ₁ is turned on is searched, and the evaluation function is shown as f (×, 1, ×, 1,1,1). It is assumed that the control element x ₂ (for example, ISC unit 1) to be searched is retrieved. In that case, as shown in the time chart of the figure, prior to the ON operation of the control element x ₁ , the control element x _{2 with} a large torque change amount, that is, the output of the ISC unit 1 is increased stepwise. At the same time, the operation of the ISC unit 1 is stopped together with the ON operation of the control element x ₁ .

As shown in FIG. 9, the evaluation function is f (1,
X, 0, x, x, 0) The control element x ₁ whose torque change speed is fast and whose timing cannot be delayed
It is assumed that the control element x ₂ indicated by f (×, 1, ×, 1,1,0) is in the ON state when is turned on. In such a case, even if the control element x ₂ is turned off, the decrease speed of the drive torque is slow, so an engine control element that can absorb the difference is searched for. As a result, if the control element x ₃ (for example, the ESA unit 3) whose evaluation function is represented by f (1, ×, ×, ×, ×, 1) is searched, as shown in the time chart of FIG. The driving force of the control element x ₂ is reduced in synchronism with the ON operation of the control element x ₁ , and at the same time, the control element x ₃ having a fast torque change speed is operated in order to prevent a decrease in responsiveness during that period. become. Therefore, abrupt torque change during ON operation of the control element x ₁ is suppressed.

[0040]

As described above, according to the present invention, since the load element is controlled based on the drive form information in which the drive form of each load element is coded, the main part of the control is common. Therefore, even if the installation conditions and characteristics of the auxiliary machinery are different, it is only necessary to change only the coded data part.

In particular, according to the second and third aspects of the invention, when the change of the driving force due to the change of the load is suppressed by the control of the load element, it is sufficient to change the drive state of the minimum load element. This makes it possible to minimize the sacrifice of the load element.

[Brief description of drawings]

FIG. 1 is a control system diagram of an engine.

FIG. 2 is a flowchart showing a control operation of the embodiment.

FIG. 3 is an explanatory diagram showing a control example of the embodiment.

FIG. 4 is an explanatory diagram showing a control example of the embodiment.

FIG. 5 is an explanatory diagram showing a control example of the embodiment.

FIG. 6 is an explanatory diagram showing a control example of the embodiment.

FIG. 7 is an explanatory diagram showing a control example of the embodiment.

FIG. 8 is an explanatory diagram showing a control example of the embodiment.

FIG. 9 is an explanatory diagram showing a control example of the embodiment.

[Explanation of symbols]

4 Main control unit

Continued front page    (72) Inventor Shigeo Kato             3-1, Shinchi, Fuchu-cho, Aki-gun, Hiroshima Prefecture Mazda             Within the corporation

Claims (6)

[Claims] 1. A control device for an engine having a plurality of load elements that operate at engine output, wherein drive form information storage means stores drive form information in which drive forms for each load element are coded, and load elements. When the drive request signal for operating the is input, the operating state of the other load element is detected, and the change in the driving force when the load element indicated by the drive request signal is activated is canceled. A load element search means for searching the load element based on the drive form information stored in the storage means, and a load for controlling the searched load element and the load element for which a drive request is made so that the engine output does not fluctuate in rotation. An engine control device comprising element control means. 2. A control device for an engine having a plurality of load elements that operate at engine output, wherein drive form information storage stores drive form information in which the drive form for each load element is divided into a plurality of factors and coded. And a driving request signal for operating the load element, the operating state of another load element is detected to cancel the change in the driving force when the load element indicated by the driving request signal operates. A load element indicating a different drive form based on the drive form information stored in the storage means, and when there are a plurality of corresponding load elements, a predetermined priority determined for each factor. Load element selection means for selecting a load element according to the order, and load element control for controlling the selected load element and the load element for which drive is requested so that rotation fluctuation does not occur in the engine output. And a control means for the engine. 3. A control device for an engine having a plurality of load elements that operate at engine output, wherein drive form information storage stores drive form information in which drive forms for each load element are divided into a plurality of factors and coded. And a driving request signal for operating the load element, the operating state of another load element is detected to cancel the change in the driving force when the load element indicated by the driving request signal operates. A load element indicating a different drive form based on the drive form information stored in the storage unit, and a plurality of corresponding load elements, and when the factors of each load element are common, The load element selecting means for selecting a load element having a small arithmetic mean of the numerical values indicating the predetermined priorities determined for each factor, and the selected load element and the load element having a drive request are activated. An engine control device, comprising: load element control means for controlling rotation of the gin output so as not to vary. 4. A control device for an engine having a plurality of load elements that operate at engine output, comprising: drive form information storage means for storing drive form information in which drive forms for each load element are coded; and load elements. When the drive request signal for operating the is input, the operating state of the other load element is detected, and the change in the driving force when the load element indicated by the drive request signal is activated is canceled. A load element search means for searching the load element based on the drive form information stored in the storage means, and a load for controlling the searched load element and the load element for which a drive request is made so that the engine output does not fluctuate in rotation. An element control unit and an engine output adjusting unit that adjusts the engine output so that the engine output does not fluctuate when the load element that has a drive request operates when the corresponding load element does not exist. An engine control device comprising a gin output adjusting means. 5. A control device for an engine having a plurality of load elements that operate at engine output, wherein drive form information storage means stores drive form information in which drive forms for each load element are coded, and the load element. When the drive request signal for operating the is input, the operating state of the other load element is detected, and the change in the driving force when the load element indicated by the drive request signal is activated is canceled. A load element search means for searching the load element based on the drive form information stored in the storage means, and a load for controlling the searched load element and the load element for which a drive request is made so that the engine output does not fluctuate in rotation. If the element control means and the corresponding load element do not exist, the ignition timing is retarded in advance, and the ignition timing control is advanced to advance the ignition timing when the load element that is requested to drive is activated. An engine control device comprising: a control means. 6. The driving mode of the load element is constituted by at least a plurality of factors including a torque change speed, a torque change amount, timing operability, and torque variability.
The engine control device according to any one of 1.