JP3465621B2 - Relay drive circuit controller - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control device for a relay drive circuit which can continuously supply a necessary current to an external load such as a solenoid, and can ensure a stable operation of the external load.

[0002]

2. Description of the Related Art As a conventional technique of this kind, there is one described in Japanese Patent Laid-Open No. 9-81212.

[0003]

In the prior art, two pulse generating circuits for generating first and second pulses each having a fixed pulse width are switched to excite the relay coil,
The power consumption of the relay output circuit is reduced and the relay output response time is shortened. However, when considering driving an external load such as a solenoid with a relay controlled by such an output circuit, when the solenoid has a small heat capacity, or the solenoid is mounted at a position where it is likely to receive heat from the surroundings. In this case, the temperature of the solenoid increases greatly, and the internal resistance of the solenoid increases. As described above, in the related art, since it is not configured to supply the current that should originally be supplied to the solenoid,
The operation of the solenoid becomes unstable, and in the worst case, the solenoid may be thermally destroyed.

The present invention has been made by paying attention to such a conventional problem, and it is possible to supply a current whose temperature rise is suppressed to an external load to ensure a stable operation and to externally An object of the present invention is to provide a control device for a relay drive circuit that can protect a load.

[0005]

In order to solve the above-mentioned problems, the invention according to claim 1 supplies a drive current to a relay coil for driving a relay contact, and supplies an external load connected to the relay contact with a current. In a controller of a relay drive circuit for driving, a first drive current control means for supplying a first drive current to the relay coil only for a prescribed time to turn on the relay contact, and the relay contact are defined as described above. Voltage detecting means for detecting a voltage generated in the external load when turned on only for a time; current detecting means for detecting a current flowing through the external load when the relay contact is turned on only for the prescribed time; and the voltage Resistance detecting means for detecting the resistance value of the external load based on the voltage detected by the detecting means and the current detected by the current detecting means; and the resistance detecting means. The current value to be supplied to the external load is determined based on the detected resistance value, and the second drive current of the PWM waveform having the duty ratio corresponding to the current value to be supplied to the external load is applied to the relay coil. Second to supply to
The gist is to have a drive current control means. With this configuration, the resistance detecting means detects the actual resistance of the external load such as a solenoid, and the current value to be supplied to the external load is determined based on this actual resistance. Then, the duty ratio of the PWM waveform current supplied to the relay coil is changed, and the current determined based on the actual resistance flows through the external load.

According to a second aspect of the present invention, in the control device for the relay drive circuit according to the first aspect, the current monitoring means for monitoring the current flowing through the external load, and the current flowing through the external load are equal to or more than a specified value. The present invention is characterized in that it has stop means for stopping the supply of the drive current to the relay coil by the first and second drive current control means according to the output of the current monitoring means when it becomes low. With this configuration, when a current more than the specified value flows in the external load circuit due to an abnormality or the like, the supply of the drive current to the relay coil is stopped, the relay contact is turned off, and the external load circuit is opened.

[0007]

According to the first aspect of the present invention, the first drive current control means for supplying the first drive current to the relay coil only for the specified time to turn on the relay contact, and the relay contact are Voltage detection means for detecting a voltage generated in an external load when turned on only for a specified time; and current detection means for detecting a current flowing through the external load when the relay contact is turned on only for the specified time, Resistance detection means for detecting the resistance value of the external load based on the voltage detected by the voltage detection means and the current detected by the current detection means, and the external load based on the resistance value detected by the resistance detection means Current value to be supplied to the relay coil, and a second drive current having a PWM waveform having a duty ratio corresponding to the current value to be supplied to the external load is supplied to the relay coil. Since the two drive current control means are provided, a current determined based on the actual resistance of the external load can be applied to the external load regardless of the small heat capacity of the external load or the mounting position, and the temperature rise can be suppressed. As a result, stable operation can be ensured and an external load can be protected.

According to the second aspect of the present invention, the current monitoring means for monitoring the current flowing through the external load, and the output of the current monitoring means when the current flowing through the external load exceeds a specified value, Since the stop means for stopping the supply of the drive current to the relay coil by the first and second drive current control means is provided, the relay contact is opened when a current exceeding a specified value flows in the external load circuit due to an abnormality or the like. It can be turned off immediately to protect external loads.

[0009]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

1 and 2 are views showing an embodiment of the present invention. First, the configuration of the control device of the relay drive circuit will be described with reference to FIG. MOSFET Q ₁ as a first relay coil 1a and the switching means of the relay 1 to the power source V _{IN 1} are connected in series is controlled power supply.
r _L is a relay resistance and L is a relay inductance.
A flywheel diode D is connected in parallel to the relay 1. In addition, the second power source V _IN2 which is the load side power source
A relay contact 1b in the relay 1, a current detection resistor R _s for detecting a load current, and a solenoid 2 as an external load.
Are connected in series. Solenoid 2 has internal resistance R
Has _SOL and inductance L _SOL . On the other hand, 3
Is a microcomputer that is a control system, and includes a voltage monitor unit 3a as a voltage detection unit for detecting a voltage applied to the solenoid 2, a current monitor unit 3b, a first switching control unit 3c as a first drive current control unit, Each function of the second switching control means 3d as the second drive current control means and the resistance detection means for detecting the internal resistance value of the solenoid 2 is provided. Reference numeral 4 denotes a current sensor, which captures a voltage drop generated in the current detection resistor R _{s due} to the current flowing in the solenoid 2 and sends a detection output to the current monitor unit 3b. The current detection resistor R _s , the current sensor 4, and the current monitor 3b constitute current detection means for detecting the current flowing through the solenoid 2. Each drive signal line from the first switching control means 3c and the second switching control means 3d is connected to the gate of the MOSFET Q ₁ via the OR gate 5.

Next, the operation will be described with reference to FIG. Figure 2
(A) is the first drive pulse from the first switching control means 3c, (b) is the second drive pulse from the second switching control means 3d, (c) is the voltage monitoring section 3a. Detection timing, and FIG. 3D shows the detection timing of the current monitor unit 3b. At the start of control, the first
The MOSFET Q ₁ is turned on by the first drive pulse (FIG. 2 (a)) from the switching control means 3c to drive the relay coil 1a, and the relay contact 1b is maintained for a prescribed time t ₁ only.
Turn on. When the relay contact 1b is turned on, a drive current flows from the second power source V _IN2 to the solenoid 2 and the current detection resistor R _s only for t ₁ hours. Applied voltage V at this time
_IN2 is monitored by the voltage monitor unit 3a (Fig. 2 (c)),
By monitoring the current I ₀ with the current monitor unit 3b (FIG. 2 (d)), the initial resistance R _SOL0 of the solenoid 2 which is the external load is obtained from the following equation. At this time, γ is the temperature coefficient (known) of the solenoid internal resistance R _SOL , ΔT is the temperature rise amount, and t ₁ time is considered to be γ × ΔT = 0 if it is made as short as possible in consideration of the time constant of the solenoid 2. _Therefore , R _SOL =
_Become R _SOL0 ,

## EQU1 ## R _SOL = (V _IN2 / I ₀ ) −R _s −R _ON (1) Here, R _ON is the ON resistance of the relay contact 1b (t =
0 is known). From the above result, the duty for obtaining the current I to be supplied to the solenoid 2 is determined by the applied voltage V
It is calculated using _IN2 and the solenoid resistance R _SOL , and this is used as the second drive pulse having the PWM waveform from the second switching control means 3d (FIG. 2 (b)). After the lapse of t ₂ seconds, the driving by the second switching control means 3d is stopped, and the above operation by the first switching control means 3c is repeated to obtain R _SOL . At this time, the actual decrease or increase of the applied current becomes ΔR _SOL . ΔR _SOL = ΔT × γ, R _s = R _s0 , R
_{When ON} = R _ON0 and V _IN2 = V _IN0 ,

## _EQU00002 ## R _SOL = R _SOL0 + ΔR _SOL (V _IN2 / I) -R _s -R _ON = (V _IN0 / I ₀ ) -R _s0 -R _ON0 + ΔT · γ ΔT = {[V _IN2 (1 / I ) − (1 / I ₀ )]} / γ (2) Since the temperature rise of the solenoid 2 can be estimated from this result, if the temperature is equal to or higher than the solenoid heat resistant temperature, the driving by the second switching control means 3d is stopped. To do. If it is lower than the solenoid heat resistant temperature, the calculated R
The second switching control means 3d has a duty that can maintain the current I to be supplied to the solenoid 2 from _SOL and V _IN2.
The second drive pulse from is changed and output. To give a numerical example, in the initial state, I = 2A, R _SOL = 3Ω, V
_{If IN2} = 12V, I = (V _IN2 / R _SOL ) × Du
Duty = 50% from ty. Therefore, if R _SOL =
If 6Ω, Duty = 100%, R _SOL = 1.5Ω
Then, Duty = 25%.

3 and 4 show another embodiment of the present invention. The present embodiment has a comparator 6 with hysteresis as a current monitoring means for monitoring the upper end voltage of the current detection resistor R _s , that is, the current flowing through the solenoid 2 as compared with the above-described embodiments. Q ₂ is a switching element as stop means, C is a capacitor, and R ₁ is a resistor. Then, when a current greater than or equal to Imax specified for protecting the solenoid 2 flows when the resistance value of the load circuit suddenly decreases (Imax is V _ref = Imax × (R _s + R
_SOL ) or more), the switching element Q ₂ is immediately turned on and the MOSFET Q ₁ is turned off by the output of the comparator 6 regardless of the output of the microcomputer 3 to turn off the relay coil 1
The drive current supply to a is stopped. In order to prevent abnormal oscillation, as shown in FIG. 4C, once the switching element Q ₂ is turned on, the on state of the switching element Q ₂ continues for a certain period of time t ₃ , and The detection information is transmitted to the microcomputer 3, and then the control is stopped.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a control device for a relay drive circuit according to an embodiment of the present invention.

FIG. 2 is a timing chart of drive pulses and the like for explaining the operation of the above embodiment.

FIG. 3 is a circuit diagram of another embodiment of the present invention.

FIG. 4 is a timing chart of drive pulses and the like for explaining the operation of the other embodiment.

[Explanation of Codes] 1 relay 1a relay coil 1b relay contact 2 solenoid (external load) 3 microcomputer 3a voltage monitor unit (voltage detection unit) 3b current monitor unit 3c which constitutes current detection unit together with current sensor and current detection resistor 1 switching control means (first drive current control means) 3d 2nd switching control means (second drive current control means) 4 current sensor 6 comparator with hysteresis (current monitoring means) Q ₂ switching element (stopping means) R _s Current detection resistor

─────────────────────────────────────────────────── ─── Continuation of the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H02M 3/155 G05F 1/10 H03K 17/695

Claims (2)

(57) [Claims] 1. A control device of a relay drive circuit for supplying a drive current to a relay coil for driving a relay contact to drive an external load connected to the relay contact with current, wherein a first drive current is applied to the relay coil. First drive current control means for supplying only a specified time to turn on the relay contact, and voltage detection means for detecting a voltage generated in the external load when the relay contact is turned on only for the specified time, Current detecting means for detecting a current flowing through the external load when the relay contact is turned on only for the specified time, and the external voltage based on the voltage detected by the voltage detecting means and the current detected by the current detecting means. A resistance detecting means for detecting a resistance value of the load, and a current value to be supplied to the external load is determined based on the resistance value detected by the resistance detecting means. A second drive current control means for supplying to the relay coil a second drive current having a PWM waveform having a duty ratio corresponding to a current value to be supplied to the external load. Control device. 2. The first and second drive currents are controlled by a current monitoring unit that monitors a current flowing through the external load and an output of the current monitoring unit when the current flowing through the external load exceeds a specified value. The control device of the relay drive circuit according to claim 1, further comprising a stop unit that stops the supply of the drive current to the relay coil by the control unit.