U.S. patent application number 17/236302 was filed with the patent office on 2021-08-05 for automobile charger.
The applicant listed for this patent is PILOT INC.. Invention is credited to Calvin Shiening WANG, Chung-Hsin WANG.
Application Number | 20210237591 17/236302 |
Document ID | / |
Family ID | 1000005527142 |
Filed Date | 2021-08-05 |
United States Patent
Application |
20210237591 |
Kind Code |
A1 |
WANG; Calvin Shiening ; et
al. |
August 5, 2021 |
AUTOMOBILE CHARGER
Abstract
A novel automobile charger which comprise a direct current
voltage, wherein a positive pole of the direct current voltage is
connected with one end or lead of a DC to DC module, one end of a
battery voltage detection module and one end of a load module
simultaneously, while a negative pole of the battery is connected
with the other end of the DC to DC module, one end of a
microcontroller, one end of the automobile start control module and
the other end of the battery voltage detection module
simultaneously. A third end of the DC to DC module is connected
with the other end of the microcontroller, the other three ends of
which are connected with the third end of the battery voltage
detection module, the other end of the automobile start control
module and one end of the load detection module respectively. The
other end of the load detection module is connected with the third
end of the automobile start control module and the other end of the
load module simultaneously.
Inventors: |
WANG; Calvin Shiening; (City
of Industry, CA) ; WANG; Chung-Hsin; (Shenzhen,
CN) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
PILOT INC. |
City of Industry |
CA |
US |
|
|
Family ID: |
1000005527142 |
Appl. No.: |
17/236302 |
Filed: |
April 21, 2021 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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17131113 |
Dec 22, 2020 |
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17236302 |
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16404321 |
May 6, 2019 |
10875410 |
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17131113 |
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15923219 |
Mar 16, 2018 |
10328806 |
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16404321 |
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15355409 |
Nov 18, 2016 |
10046653 |
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15923219 |
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14569352 |
Dec 12, 2014 |
9525297 |
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15355409 |
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Current U.S.
Class: |
1/1 |
Current CPC
Class: |
B60L 53/00 20190201;
H02J 7/0029 20130101; H02J 9/005 20130101; H02J 7/0034 20130101;
B60L 53/53 20190201; H02J 2207/20 20200101; H02J 7/0068
20130101 |
International
Class: |
B60L 53/00 20060101
B60L053/00; B60L 53/53 20060101 B60L053/53; H02J 7/00 20060101
H02J007/00 |
Foreign Application Data
Date |
Code |
Application Number |
Apr 28, 2014 |
CN |
201420212173.5 |
Claims
1-6. (canceled)
7. An Apparatus for jump starting a vehicle engine, comprising: an
internal power supply; an output port having positive and negative
polarity outputs; a vehicle battery isolation sensor connected in
circuit with said positive and negative polarity outputs,
configured to detect presence of a vehicle battery connected
between said positive and negative polarity outputs; a reverse
polarity sensor connected in circuit with said positive and
negative polarity outputs, configured to detect polarity of a
vehicle battery connected between said positive and negative
polarity outputs and to provide an output signal indicating whether
positive and negative terminals of said vehicle battery are
properly connected with said positive and negative polarity outputs
of said output port; a power switch connected between said internal
power supply and said output port; and a microcontroller configured
to receive input signals from said vehicle isolation sensor and
said reverse polarity sensor, and to provide an output signal to
said power switch, such that said power switch is turned on to
cause said internal power supply to be connected to said output
port in response to signals from said sensors indicating the
presence of a vehicle battery at said output port and proper
polarity connection of positive and negative terminals of said
vehicle battery with said positive and negative polarity outputs,
and is not turned on when signals from said sensors indicate either
the absence of a vehicle battery at said output port or improper
polarity connection of positive and negative terminals of said
vehicle battery with said positive and negative polarity
outputs.
8. The apparatus of claim 7, wherein said power switch comprises a
plurality of FETs in parallel.
9. The apparatus of claim 7, further comprising a voltage
measurement circuit configured to measure output voltage of said
internal power supply and to provide a voltage measurement signal
to said microcontroller.
10. The apparatus of claim 7, further comprising a voltage
regulator configured to convert output voltage of said internal
power supply to a voltage level appropriate to provide operating
power to internal components of the apparatus.
11. An apparatus for jump starting a vehicle having a depleted or
discharged vehicle battery with positive and negative polarity
terminals, the apparatus comprising: a power supply; a positive
polarity vehicle battery terminal connector; a negative polarity
vehicle battery terminal connector; a vehicle battery isolation
sensor connected in circuit with the positive and negative polarity
vehicle battery terminal connectors, the vehicle battery isolation
sensor configured to detect a presence of the vehicle battery when
connected between the positive and negative polarity vehicle
battery terminal connectors; a reverse polarity sensor connected in
circuit with the positive and negative polarity vehicle battery
terminal connectors, the reverse polarity sensor configured to
detect a polarity of the vehicle battery connected between the
positive and negative polarity vehicle battery terminal connectors
and to provide an output signal indicating that the positive and
negative polarity terminals of the vehicle battery are properly
connected to the positive and negative polarity vehicle battery
connectors; a power switch connected between the power supply and
the positive and negative polarity vehicle battery terminal
connectors; and a microcontroller configured to receive input
signals from the vehicle isolation sensor and the reverse polarity
sensor, the microcontroller is configured to provide an activating
output signal to turn on the power switch to cause the power supply
to be connected to the positive and negative polarity vehicle
battery connectors in response to the microcontroller receiving
input signals simultaneously from the sensors indicating both the
presence and connection of the vehicle battery to the positive and
negative polarity vehicle battery connectors and proper polarity
connection of the positive and negative polarity terminals of the
vehicle battery with the positive and negative polarity battery
terminal connectors, and the microcontroller is configured to
provide a deactivating output signal to turn off the power switch
to cause the power supply to be disconnected from the positive and
negative polarity vehicle battery connectors in response to the
microcontroller receiving input signals from the sensors indicating
the absence of the vehicle battery connected to the positive and
negative polarity vehicle battery connectors and/or improper
polarity connection of the positive and negative polarity terminals
of the vehicle battery to the positive and negative polarity
vehicle battery connectors.
12. The apparatus of claim 7, wherein the power switch comprises a
plurality of FETs in parallel.
13. The apparatus of claim 7, further comprising separate visual
indicators configured to display the power on status of the
apparatus, and the jump start boost power status of power supplied
to the positive and negative polarity vehicle battery terminal
connectors.
14. The apparatus of claim 7, further comprising a voltage
measurement circuit configured to measure output voltage of the
power supply and to provide a voltage measurement signal to the
microcontroller.
15. The apparatus of claim 7, further comprising a voltage
regulator configured to convert output voltage of the power supply
to a voltage level appropriate to provide operating power to
electrical components of the apparatus.
16. The apparatus according to claim 7, wherein the vehicle battery
isolation sensor detects presence or absence of the vehicle battery
prior to any initial connection and is not reliant upon any
pre-established connection or operation of the circuit with the
positive and negative polarity battery terminal connectors.
17. The apparatus of claim 7, further comprising a visual indicator
configured to warn a user when a vehicle battery is connected with
reverse polarity.
18. The apparatus of claim 7, wherein the microcontroller is
configured to control at least one LED to provide a visual alarm
indicating an emergency situation.
19. An apparatus for jump starting a vehicle having a depleted or
discharged vehicle battery with positive and negative polarity
terminals, the apparatus comprising: a power supply; a positive
polarity vehicle battery terminal connector; a negative polarity
vehicle battery terminal connector; a vehicle battery isolation
sensor connected in circuit with the positive and negative polarity
vehicle battery terminal connectors, the vehicle battery isolation
sensor configured to detect a presence of the vehicle battery when
connected between the positive and negative polarity vehicle
battery terminal connectors; a reverse polarity sensor connected in
circuit with the positive and negative polarity vehicle battery
terminal connectors, the reverse polarity sensor configured to
detect a polarity of the vehicle battery connected between the
positive and negative polarity vehicle battery terminal connectors
and to provide an output signal indicating that the positive and
negative polarity terminals of the vehicle battery are properly
connected to the positive and negative polarity vehicle battery
connectors; a power switch connected between the power supply and
the positive and negative polarity vehicle battery terminal
connectors; and a microcontroller configured to receive input
signals from the vehicle isolation sensor and the reverse polarity
sensor, the microcontroller configured to control operation of the
power switch, wherein the microcontroller is configured to turn on
the power switch when receiving input signals from the vehicle
isolation sensor and reverse polarity sensor indicating both the
presence and connection of the vehicle battery to the positive and
negative polarity vehicle battery connectors and proper polarity
connection of the positive and negative polarity terminals of the
vehicle battery with the positive and negative polarity battery
terminal connectors, and wherein the microcontroller is configured
to turn off the power switch when receiving input signals from the
sensors indicating the absence of the vehicle battery connected to
the positive and negative polarity vehicle battery connectors
and/or improper polarity connection of the positive and negative
polarity terminals of the vehicle battery to the positive and
negative polarity vehicle battery connectors.
20. An apparatus for jump starting a vehicle having a depleted or
discharged vehicle battery with positive and negative polarity
terminals, the apparatus comprising: a power supply; a positive
polarity vehicle battery terminal connector; a negative polarity
vehicle battery terminal connector; a vehicle battery isolation
sensor connected in circuit with the positive and negative polarity
vehicle battery terminal connectors, the vehicle battery isolation
sensor configured to detect a presence of the vehicle battery when
connected between the positive and negative polarity vehicle
battery terminal connectors; a reverse polarity sensor connected in
circuit with the positive and negative polarity vehicle battery
terminal connectors, the reverse polarity sensor configured to
detect a polarity of the vehicle battery connected between the
positive and negative polarity vehicle battery terminal connectors
and to provide an output signal indicating that the positive and
negative polarity terminals of the vehicle battery are properly
connected to the positive and negative polarity vehicle battery
connectors; a power switch connected between the power supply and
the positive and negative polarity vehicle battery terminal
connectors; and a microcontroller configured to receive input
signals from the vehicle isolation sensor and the reverse polarity
sensor, the microcontroller is configured to turn on the power
switch to cause the power supply to be connected to the positive
and negative polarity vehicle battery connectors in response to the
microcontroller receiving input signals simultaneously from the
sensors indicating both the presence and connection of the vehicle
battery to the positive and negative polarity vehicle battery
connectors and proper polarity connection of the positive and
negative polarity terminals of the vehicle battery with the
positive and negative polarity battery terminal connectors, and the
microcontroller is configured to turn off the power switch to
prevent the power supply from being connected to the positive and
negative polarity vehicle battery connectors in response to the
microcontroller not receiving the input signals simultaneously from
the sensors indicating both the presence and connection of the
vehicle battery to the positive and negative polarity vehicle
battery connectors and proper polarity connection of the positive
and negative polarity terminals of the vehicle battery with the
positive and negative polarity battery terminal connectors.
Description
RELATED APPLICATIONS
[0001] This application claims the benefit of priority of Chinese
application no. 201420212173.5 filed Apr. 28, 2014, the entire
content of which is incorporated herein by reference.
BACKGROUND
[0002] The present disclosure relates to an automobile charging
device, in particular relates to a novel automobile charger with a
safe power supply charging quickly.
[0003] Automobile charging is a big issue of traveling by
automobile for those automobile fans and businessmen, the maturity
of the technology thereof is one of the critical factors
restricting the application of the automobile charger. However,
current automobile chargers have common problems of not able to
automatically detect whether a load is connected, whether an
electrode is connected with an automobile storage battery
reversely, whether an automobile engine or the storage battery has
a reverse current, whether the battery state is suitable for heavy
current power generation and so on. Accordingly, the present
disclosure provides a novel automobile charger with the safe power
supply charging quickly to solve the problems mentioned above, thus
making the automobile charging safe, quick, mature and
propagable.
SUMMARY
[0004] A purpose of the present disclosure aims to provide a novel
automobile charger with the safe power supply charging quickly, in
order to solve the problems presented in the above background.
[0005] To achieve the purpose described above, the present
disclosure provides the following technical solutions: a novel
automobile charger comprises a direct current power supply, wherein
a positive pole of the direct current power supply is connected
with one end of a DC to DC module, one end of a battery voltage
detection module and one end of a load module simultaneously, while
a negative pole of the direct current voltage is connected with the
other end of the DC to DC module, one end of a micro controller,
one end of an automobile start control module and the other end of
the battery voltage detection module simultaneously. A third end of
the DC to DC module is connected with the other end of the
microcontroller, and the other three ends of the microcontroller
are connected with the third end of the battery voltage detection
module, the other end of the automobile start control module and
one end of the load detection module respectively, wherein the
other end of the load detection module is connected with the third
end of the automobile start control module and the other end of the
load module simultaneously; the load module which comprises the
automobile storage battery and the automobile engine is located on
the end of the load module.
[0006] As a further solution of the present disclosure that: the DC
to DC module provides a stable voltage for the microcontroller
which collects relevant data to conduct the corresponding control.
The battery voltage detection module conducts the measurement of
the batter voltage, the automobile start control module conducts
the power supply or the power outage for the load module through
the microcontroller, and the load detection module which comprises
the automobile storage battery or the automobile engine detects
whether the load module is correctly connected.
[0007] As a further solution of the present disclosure that: the
circuit employs an electronic switch to supply power to the load
module, which can offer more protection for the product, or reduce
the product size and the material cost.
[0008] As a further solution of the present disclosure that: the
battery voltage detection module provides protection for the power
supply battery to prevent damages caused by the discharging of the
direct current power supply.
[0009] As a further solution of the present disclosure that: the
load detection module prevents improper operations of the user.
[0010] As a further solution of the present disclosure that: in the
standby mode, the microcontroller closes all outputs when the
voltage of the direct current power supply is lower than that of
the state being able to supply power and then recovers when it is
higher than that of the state being able to supply power.
[0011] As a further solution of the present disclosure that: the
automobile start control module is the electronic switch.
[0012] Compared to the prior art, the present disclosure has the
beneficial effects that:
[0013] 1. The present disclosure employs the electronic switch to
control the supply power for the load, this part can offer more
protection for the product, and reduce the product size and the
material cost.
[0014] 2. The battery detection of the present disclosure can
provide low voltage protection to prevent damages caused by the
over discharging of the battery.
[0015] 3. The load detection of the present disclosure can prevent
improper operations by the user, such as reversed polarity, which
causes damages to the automobile or the direct current power
supply.
[0016] 4. The present disclosure employs the voltage backflow
protection for abnormal load, wherein the automobile start line is
closed to protect the battery when the abnormal voltage is
detected.
[0017] 5. The present disclosure has a fast charging function, and
can be installed fixedly or moved portably according to the use
requirements of people.
[0018] 6. The automatic detection module of the present disclosure
can automatically detects whether the load is connected, whether
the electrode is connected with the automobile storage battery
reversely, whether the automobile engine or the storage battery has
reverse current, whether the battery state is suitable for heavy
current power generation, thereby protecting the load and the
circuit and thus has complete functions.
BRIEF DESCRIPTION OF DRAWINGS
[0019] FIG. 1 is a block diagram for the principle of the emergency
power supply of the safe intelligent automobile;
[0020] FIG. 2 is a circuit diagram for the emergency power supply
of the safe intelligent automobile.
[0021] In figures: 1--DC to DC module, 2--microcontroller,
3--battery voltage detection module, 4--automobile start control
module, 5--load detection module, 6--load module, 7--direct current
power supply.
DETAILED EMBODIMENTS
[0022] The technical solutions of the present disclosure will be
described more clearly and fully in conjunction with drawings in
the embodiments of the present disclosure, and obviously, the
described embodiments are merely a part of the embodiments of the
present disclosure, not all the embodiments. Based on the
embodiments of the present disclosure, all the other embodiments
obtained by the ordinary skilled in the art without creative labors
belong to the scope claimed by the present disclosure.
[0023] Refer to FIG. 1, a novel automobile charger comprises a
direct current power supply, wherein the positive pole of the
direct current power supply is connected with one end or lead of
the DC to DC module, one end of the battery voltage detection
module and one end of the load module simultaneously, while the
negative pole of the direct current voltage is connected with the
other end of the DC to DC module, one end of the microcontroller,
one end of the automobile start control module and the other end of
the battery voltage detection module simultaneously. A third end of
the DC to DC module is connected with the other end of the
microcontroller, and the other three ends of the microcontroller
are connected with the third end of the battery voltage detection
module, the other end of the automobile start control module and
one end of the load detection module respectively, wherein the
other end of the load detection module is connected with the third
end of the automobile start control module and the other end of the
load module simultaneously; the load module which comprises the
automobile storage battery and the automobile engine is located on
the end of the load module.
[0024] Refer to FIG. 2, the DC to DC module comprises a diode D1, a
resistor R1, capacitor C1, a HT7530 voltage stabilizing tube,
capacitors C2 and C3, wherein the positive pole of the diode D1 is
connected with the positive pole of the battery, the negative pole
of the diode D1 is connected with one end of the capacitor C1 and
an IN port of the HT7530 voltage stabilizing tube simultaneously
through the resistor R1, and an OUT port of the HT7530 voltage
stabilizing tube is connected with one end of the capacitor C2, one
end of the capacitor C3 and a VDD port of the microcontroller U2,
while the other end of the capacitor C1, the other end of the
capacitor C2 and the other end of the capacitor C3 as well as a GND
port of the HT7530 voltage stabilizing tube are grounded and
connected with the negative pole of the battery simultaneously; a
R1 port of the microcontroller U2 is connected with the negative
pole of the battery through a light-emitting diode L1 and a
resistor R12 which are in series connection, a B1 port of the
microcontroller U2 is connected with a EN port of the automobile
start control module, a V0 port of the microcontroller U2 is
connected with the negative pole of the battery through a capacitor
C4 and a resistor R7 which are in parallel connection, the V0 port
is also connected with the VDD port through a slide rheostat RT, a
V1 port of the microcontroller U2 is also connected with the
negative pole of the battery through a resistor 10, a capacitor C6
and a resistor R13 which are in parallel connection, the V1 port is
connected with the positive pole of the battery through a resistor
R2, and is also connected with the negative pole of the automobile
storage battery and the automobile engine simultaneously through a
resistor R9, wherein two ends of the automobile storage battery are
in parallel connection with the capacitor C7, resistors R9, 10, a
capacitor C6 and a resistor R13 to form the load detection module
together, a V4 port of the microcontroller U2 is grounded through a
capacitor C5, a VSS port of the microcontroller U2 and one end of
the capacitor C4 are grounded simultaneously. The other end of the
capacitor C4 is connected with the VDD port of the microcontroller
U2, the resistors R2, R13 and capacitor C6 form the battery voltage
detection module together, and a Drive port of the automobile start
control module is connected with the automobile engine and one end
of a resistor R14 simultaneously, wherein the other end of the
resistor R14 is grounded.
[0025] The DC to DC module in the present disclosure provides the
stable voltage for the microcontroller which collects relevant data
to conduct the corresponding control. The battery voltage detection
module conducts the measurement of the batter voltage, and the
automobile start control module conducts the power supply or the
power outage for the load module through the microcontroller,
wherein the load detection module detects whether the load module
is correctly connected.
[0026] The microcontroller in the present disclosure determines
whether the automobile storage battery is connected with the
automobile engine through the load detection module, wherein the
automobile start control model is automatically activated and the
battery starts to supply power to the load module when the load is
correctly connected; the automobile start control model is
automatically deactivated and the battery stops supplying power to
the load module when assuming that the load is not connected or the
positive and negative polarities are reversely connected. In the
standby mode, the microcontroller closes all outputs when the
battery voltage is lower than 9V, and recovers the normal operation
only when the battery voltage is larger than 10V; the automobile
engine will generate the normal voltage to recharge the battery
after the automobile starts, whereas the automobile start control
module is deactivated immediately once the recharging voltage is
larger than the voltage before that battery starts the power
supply, to protect the battery from damages caused by charging with
the normal voltage; the automobile start control module is the
electronic switch, which can prevent the load from being reversely
connected and recharging of the normal voltage, thus protecting the
battery and prolonging lifespan.
[0027] The automobile engine will generate abnormal voltage to
recharge the direct current power supply after the automobile
starts, and the automobile start control module is deactivated
immediately once the recharging voltage is larger than the voltage
before the direct current power supply starts the power supply, to
protect the direct current power supply from damages caused by
charging with normal voltage charge.
[0028] It is obvious for the skilled people in the art that the
present disclosure is not merely limited to the details of the
above exemplary embodiments, and the present disclosure can be
implemented in other specific forms without departing from the
sprits or the basic features of the present disclosure. Thus, no
matter to consider from which point of view, the embodiments should
be considered as exemplary and non-limiting. The scope of the
present disclosure is defined by the accompanying Claims rather
than the above description, therefore it is intended that all the
changes fallen within the meanings and scope of the equivalent
elements of the Claims are contained in the present disclosure. Any
drawing reference in the Claims should not be regarded as limiting
the Claims involved.
[0029] Furthermore, it should be understood that although the
specification is described according to the embodiments, but not
every embodiment includes only an independent technical solution,
this manner of description for the specification is only for
clarity, therefore the skilled people in the art should take the
Specification as a whole, and the technical solutions in various
embodiments can be combined appropriately to form other
implementations understandable for those skilled in the art.
* * * * *