Miscellaneous active electrical nonlinear devices – circuits – and – Signal converting – shaping – or generating – Having specific delay in producing output waveform
Reexamination Certificate
1999-04-26
2002-05-14
Wells, Kenneth B. (Department: 2816)
Miscellaneous active electrical nonlinear devices, circuits, and
Signal converting, shaping, or generating
Having specific delay in producing output waveform
C327S278000, C327S285000
Reexamination Certificate
active
06388491
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates of a delay circuit using charging/discharging of a capacitor and to a device using the delay circuit.
An example of a conventional delay circuit using charging/discharging of a capacitor is shown in FIG.
2
. First, the operation of this delay circuit will be described.
At an initial state, since a switch
1
is turned ON (closed) and a switch
2
is turned OFF (opened), a terminal A to which a capacitor
7
is connected has a potential of (V
1
−V
2
). In order to start the operation of this delay circuit, a signal is supplied to an input terminal
11
. When the signal enters the input terminal
11
, a control circuit
8
turns OFF the switch
1
and turns ON the switch
2
. A constant current source
12
is connected to the terminal A, and the electric charge of the capacitor
7
also connected to the terminal A is discharged.
When the potential of the terminal A reaches a potential V
3
of a reference voltage
5
, the output of a comparator
9
is inverted. Since it takes some time to discharge, this circuit is used as a delay circuit. Here, a time from the start of the operation of the control circuit
8
to the inversion of the output of the comparator
9
becomes a delay time.
This operation is shown in FIG.
3
. The horizontal axis indicates time, and the vertical axis indicates voltage. At the initial state, although the potential at the terminal A in
FIG. 2
is (V
1
−V
2
), the capacitance is discharged through constant current from a time ta when the signal is supplied to the input terminal
11
, so that the potential at the terminal A is lowered. Thereafter, when the potential at the terminal A reaches the potential V
3
of the reference voltage
5
, the output voltage of the comparator is inverted.
When a capacitance value of the capacitor
7
is C
0
, and a constant current value of the constant current source
12
is I
0
, a delay time T
0
may be represented by the following Equation 1:
T
0
=
C
0
×(
V
1
−
V
2
−
V
3
)×
I
0
[Equation 1]
When the capacitance value C
0
is made large or the constant current value I
0
is made small, the delay time can be extended. On the other hand, when the capacitance value C
0
is made small or the constant current value I
0
is made large, the delay time can be shortened.
In the case of the delay circuit using charging/discharging of the capacitor shown in
FIG. 2
as the prior art, there are problems as described below.
In the delay circuit described thus far, a problem occurs when the terminal A to which the capacitor
7
is connected is short-circuited to an abnormal voltage such as the potential V
1
. In the case where the terminal A to be connected to the capacitor
7
comes to have a voltage higher than (V
1
−V
2
), the inverted input terminal of the comparator
9
does not become lower than V
3
. Thus, the output of the comparator
9
is not inverted. This means that the delay is not realized, and the delay time is extended without limit.
FIG. 4
shows potentials at this time. The terminal A to which the capacitor
7
is connected, is connected in an abnormal state and has the potential V
1
. Thus, the voltage at the terminal A is always at the potential V
1
, and the output of the comparator
9
is not inverted.
This delay circuit is also used as a protecting circuit or an erroneous operation preventing circuit. For example, in a lithium ion battery, when a voltage becomes too high, there is a risk that it may cause a fire. Thus, an overcharge preventing circuit is provided. The delay circuit can also be used for the overcharge preventing circuit. In addition a delay circuit is also used in a charger for lithium ion batteries to set a charging time (charge stop circuit) and the like. Thus, when the terminal A to which the capacitor
7
is connected as shown in
FIG. 1
is short-circuited to a voltage higher than (V
1
−V
2
), the overcharge preventing circuit or the charge stop circuit does not work, and a very dangerous state occurs. If the delay of the charger does not work, charging is continues permanently, and heat generation of the charger and the lithium ion battery is advanced. This causes a very dangerous state such that a fire or heat generation of the apparatus may occur.
In a circuit provided for protection or improvement of safety, even if a problem occurs, some protection must work. A so-called fail-safe must be realized. In the case of the present invention, it is required that even if the delay time is shortened, an output voltage is inverted and a signal is transmitted to the outside.
SUMMARY OF THE INVENTION
In a delay circuit using charging/discharging of a capacitor to set a delay time, there is added a voltage detecting circuit for detecting whether a terminal voltage of the capacitor has exceeded a predetermined voltage range.
REFERENCES:
patent: 3831113 (1974-08-01), Ahmed
patent: 3979598 (1976-09-01), Lach
patent: 5006738 (1991-04-01), Usuki et al.
patent: 5650739 (1997-07-01), Hui et al.
patent: 5969557 (1999-10-01), Tanzawa et al.
Mukainakano Hiroshi
Yamasaki Koichi
Cox Cassandra
Wells Kenneth B.
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