JPH0555712B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a glow plug control device for a diesel engine.

[Prior art]

FIG. 1 shows a general configuration of a conventional control device of this type, and FIG. 2 shows a time chart for explaining its operation. That is, in the configuration shown in FIG. 1, reference numeral 1 is an engine key switch, and 2 is a glow plug control device. , a sensing timer 23 , a temperature level detection circuit 24 ,
Chopping timer 25, control circuit 26, glow relay output circuit 27, and preheating display timer 2
8 and an output circuit 29 for a preheating indicator lamp. 3 is the glow relay output circuit 2
A glow relay 4 is controlled by a glow relay 7, and a glow plug 4 having a positive resistance-temperature characteristic is connected in series with the glow relay 3, and is installed in each cylinder of the engine. Furthermore, 5 is a preheating indicator lamp connected to the output circuit 29 for the preheating indicator lamp, and 6 is a power battery.

Next, the operation of this conventional configuration will be described with reference to FIG. First, when the key switch 1 is turned on to the preheating start position G as shown in FIG. A constant temperature detection current is supplied, and a voltage drop occurs based on a resistance value change corresponding to the temperature in the glow plug 4 at this time. Then, this voltage drop is inverted and amplified by the inverting amplifier circuit 22, and the sensing timer 23 and the temperature level detection circuit 2
4, and the sensing timer 23 determines the energization time for the glow relay 3 based on the temperature-equivalent voltage applied and inputs it to the control circuit 26, and the temperature level detection circuit 24 determines the energization time of the glow relay 3 based on the temperature-equivalent voltage applied. It is determined whether the voltage value is below or above a voltage value determined in advance as the control target temperature To (lower limit value), and if it is below the control target temperature, an operation start signal is issued, and if it is above, an operation stop signal is issued. It is input to the chopping timer 25.

When the power is turned on as described above, regardless of whether the temperature is below or above the control target temperature, the control circuit 2
6 prohibits the output from the chopping timer 25. Therefore, when the power is turned on, the sensing timer 23 is enabled and a glow is generated as shown in C in the same figure for the energization time determined by the sensing timer 23. The glow relay 3 is turned on via the relay output circuit 27, and the current from the battery 6 is directly supplied to the glow plug 4 as shown in FIG. Since the voltage becomes the maximum voltage (battery voltage), there is no output from the constant current circuit 21 as shown in FIG. 2B, and the output from the inverting amplifier circuit 22 shows the minimum value.

On the other hand, when the energization time set by the sensing timer 23 has elapsed, the control circuit 26 turns off the glow relay 3 via the glow relay output circuit 27, cutting off the energization to the glow plug 4. Note that the time for which the glow relay 3 is energized by the sensing timer 23 after the key switch 1 is turned on to the G position is determined in inverse proportion to the temperature (resistance value) of the glow plug 4. Regardless of the initial temperature of the glow plug 4,
This means that the glow plug 4 can be heated to approximately the control target temperature.

Then, when the power to the glow plug 4 is cut off, the constant current circuit 21 is turned on again as shown in FIG. B, and as shown in FIG. 22, the output of which gradually increases as the temperature decreases. When the output of the inverting amplifier circuit 22 reaches the comparison voltage of the temperature level detection circuit 24 set corresponding to the lower limit of the control target temperature, the temperature level detection circuit 24 sends an operation start signal to the chopping timer 25. is input to turn on the stepping timer 25 for a predetermined time, and as a result of this turning on, in the control circuit 26, the time specified by the stepping timer 25 is outputted via the glow relay output circuit 27. Turn on glow relay 3 to energize glow plug 4,
Thereafter, similar operations are repeated to control the temperature of the glow plug 4 to around a temperature slightly higher than the lower limit of the control target temperature.

Then, at the same time that the key switch 1 is turned to the G position, the preheating display timer 28 is activated via the preheating display lamp output circuit 29 as shown in FIG. The preheating indicator lamp 5 is turned on for a corresponding fixed period of time, and the key switch 1 is turned on after the preheating indicator lamp 5 is turned off, as shown in FIG.
All you have to do is put the key switch 1 into the ST position and energize the starter to start the engine, and upon completion of this start, the key switch 1 returns to the ON position and ends the control.

By the way, in general, for diesel engines, when it is difficult to start the engine by normal means due to cold weather or low power battery capacity, an auxiliary battery or charger is used to perform auxiliary starting. However, in such cases, in the conventional glow plug control device with the above configuration, an excessive voltage exceeding the specified value is often applied to the glow plug, and as a result, the glow plug may be damaged by the large current. This had disadvantages such as the possibility that

[Summary of the Invention] In view of the above drawbacks of the conventional technology, the present invention adds a voltage detection circuit for detecting the power supply voltage of the power supply battery to the control device, and makes it possible to prevent overvoltage exceeding the specified value from being applied to the device. When this occurs, this overvoltage is detected by a voltage detection circuit, and the glow relay is turned off using the detection signal to prevent power from flowing to the glow plug, thereby preventing damage to the glow plug. Furthermore, if necessary, a energization blocking signal is sent to the output circuit for the preheating indicator lamp to prevent damage to the glow plug, and also to notify that an abnormality has occurred by changing the display format of the preheating indicator lamp. It is something.

[Embodiments of the invention]

Hereinafter, one embodiment of the glow plug control device according to the present invention will be described in detail with reference to FIG. 3 and FIGS. 4a and 4b.

This embodiment device in FIG. 3 is shown corresponding to the conventional device in FIG. , when the key switch 1 is turned on to the preheating start position G, the voltage of the power supply battery 6 and, although not shown, the voltage of the auxiliary power supply such as the auxiliary battery or charger inserted and connected for the above-mentioned auxiliary start is detected. , a voltage detection circuit 30 is provided which operates to prevent energization of the glow relay 3 and preheating indicator lamp 5 only when this detected voltage is equal to or higher than a predetermined set voltage value V ₁ (v).

Next, the operation of this embodiment will be described with reference to FIGS. 4a and 4b in the same manner as described above. The time chart in Fig. 4 shows when the side a in the figure is below the set voltage value V ₁ (v) and when the side b in the figure is above the set voltage value V ₁ (v), respectively. In this embodiment, the function of the voltage detection circuit 30 newly added to the control device 2 will be mainly described.

First, when the power supply voltage is lower than the set voltage value V ₁ (v), that is, when the power supply battery 6 is used for normal startup, turn the key switch 1 to the preheating start position G as shown in a to A in the same figure. Therefore, in order to detect the power supply voltage of the power supply battery 6, that is, the voltage below the set voltage value in this case, the voltage detection circuit 30 performs the following steps.
No energization blocking signal is output to the glow plug 3 and the preheating indicator lamp 5, and therefore, at this time, the normal control shown in FIGS.

Next, at the time of starting with an auxiliary battery or a charger, etc. (not shown) inserted into the power supply battery 6, if these power supply voltages are below the set voltage value V ₁ (v), this occurs. However, if this power supply voltage is higher than the set voltage value V ₁ (v), the key 1 is turned on to the preheating start position G as shown in b to A in the figure. ,
The voltage detection circuit 30 detects a voltage equal to or higher than a set voltage value and outputs a energization blocking signal. Since the power supply voltage is detected by directly monitoring the voltage of the battery 6, overvoltage is detected regardless of the position of the key switch 1. This energization blocking signal is input to the glow relay output circuit 27 and the preheating indicator lamp output circuit 29, and the energization to the glow relay 3 and the preheating indicator lamp 5 is blocked as shown in b to C and E in the figure. Therefore, while the glow plug 4 is protected from the application of overvoltage, the occurrence of the abnormality can be detected by the non-lighting of the preheating indicator lamp 5, which is normally lit during startup. Furthermore, when the glow relay 3 is turned off, power supply voltage cannot be supplied to the glow plug 4 from anywhere, so when the power supply voltage is excessive, overvoltage will be applied to the glow plug 4 regardless of the position of the key switch 1. There isn't. Even in this case, when the detected voltage returns to below the set voltage value, the energization blocking signal from the voltage detection circuit 30 disappears.
The same normal control as described above will be performed.

In the above embodiment, the control start timing is set to the preheating position G of the key switch 1, but it may also be set to the ON position, and the detection point by the voltage detection circuit 30 is from the power supply battery 6 to the glow plug 4 via the glow relay 3. It may be provided at any point on the power supply circuit, and the detected voltage value is set depending on the type of glow plug to which it is applied. Furthermore, the power supply to the preheating indicator lamp may be blocked as required, and for example, blinking means may be employed for the preheating indicator lamp in addition to the turning off means.

〔Effect of the invention〕

As detailed above, according to the present invention, in the glow plug control device for a diesel engine,
A voltage detection circuit is provided to detect the voltage applied to the glow plug, and if the voltage detected by this voltage detection circuit is an excessive voltage that exceeds the specified value, the glow relay is turned off regardless of the key switch position, and the glow plug is energized. Since the structure is designed to prevent damage to the glow plug due to excessive voltage application, it is possible to prevent damage to the glow plug regardless of the position of the key switch, and if necessary, the preheating indicator lamp can also be used at the same time to notify of abnormal conditions. It has the following features.

[Brief explanation of the drawing]

FIG. 1 is a block configuration diagram showing an overview of a conventional glow plug control device, FIG. 2 is a time chart for explaining the operation of the same device, and FIG. 3 is a glow plug control device according to an embodiment of the present invention. FIG. 4 is a block diagram showing an overview, and a time chart for explaining the operation of the apparatus shown in FIG. 3. 1...key switch, 2...control device, 21...
...Constant current circuit, 22...Inverting amplifier circuit, 23...
Sensing timer, 24... Temperature level detection circuit, 25... Chopping timer, 26... Control circuit, 27... Output circuit for glow relay, 28...
...Preheating indicator timer, 29... Output circuit for preheating indicator lamp, 30... Voltage detection circuit, 3... Glow relay, 4... Glow plug, 5... Preheating indicator lamp, 6... Power battery.

Claims (1)

[Scope of Claims] 1. A glow plug installed in each cylinder of an engine and having predetermined resistance-temperature characteristics; a glow relay connected in series to a power supply circuit between the glow plug and a power source; temperature detection means for supplying a detection current to the glow plug during the off-period of the relay to detect a temperature change based on the resistance value of the glow plug, and corresponding to the temperature detected by the temperature detection means;
Glow plug control comprising at least a timer means for determining the ON time of the glow relay, and a control circuit for controlling the glow relay on and off by the temperature detection means and the timer means to control the temperature of the glow plug. The device detects the power supply voltage of the power supply circuit of the glow plug, and when this detected voltage exceeds a specified value, the glow relay is turned off regardless of the position of the key switch, and the voltage is set to cut off the power supply circuit to the glow plug. A glow plug control device characterized by being provided with a detection means. 2. The glow plug is equipped with a preheating indicator lamp that indicates the preheating state of the glow plug, and when the voltage detected by the voltage detection means is equal to or higher than a specified value, the display format of the preheating indicator lamp is changed by the output of the detected voltage. A glow plug control device according to claim 1.