Information
-
Patent Grant
-
6662639
-
Patent Number
6,662,639
-
Date Filed
Friday, September 6, 200222 years ago
-
Date Issued
Tuesday, December 16, 200321 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Lefkowitz; Edward
- Davis; Octavia
Agents
-
CPC
-
US Classifications
Field of Search
US
- 073 1181
- 073 159
- 324 537
- 324 643
- 340 87002
- 322 28
-
International Classifications
-
Abstract
A method and apparatus for receiving and relaying signals from an ignition coil. A secondary pickup is constructed and arranged to mate with the ignition coil and to receive the secondary voltage signals. The signals can be received and relayed to an analyzer for engine evaluation through a spade that is part of the secondary pickup.
Description
FIELD OF THE INVENTION
The present invention generally relates to an apparatus and method for analysis of engines. More particularly, the present invention relates to an apparatus and method to pickup secondary ignition voltage.
BACKGROUND OF THE INVENTION
Conventional combustion, reciprocating engines are widely used as automotive engines. A conventional engine (e.g., single-cycle, two-cycle and others) is typically composed of an engine or cylinder block assembly having one or more cylinders therein. A piston is slidably disposed in the cylinder and moves reciprocally within the cylinder. A cylinder head at one end of the cylinder completes the cylinder assembly. The cylinder head typically contains the valves (intake and exhaust) and the spark plug. The spark plug typically ignites a pre-mixed fuel that is injected by the intake valve into a combustion chamber and helps to define an ignition event.
Should an ignition event not occur or the cylinder misfires, it can reduce the power output of the engine, can cause low fuel economy and poor performance. Engine analyzers are used to analyze the performance of internal combustion engines by analyzing ignition events of their cylinders.
A conventional digital analyzer can convert analog signals to digital signals for display on an oscilloscope, which displays snapshots of discrete portions of the signals as waveforms. In the case of multiple cylinders, waveforms showing the primary and the secondary ignition voltages are displayed. The voltages are acquired from a primary lead and a secondary lead (referred to as pickups) that are connected to an ignition coil at one end. The primary and secondary leads are connected at the other end to the analyzer, which runs tests and obtains data that is converted and displayed as waveforms. The secondary leads can be a capacitive pickup and the high voltage signals are capacitively sensed and converted to waveforms by the analyzer.
In newer engines, there can be one ignition coil per cylinder, referred to as “coil-on-plug”, where each coil is typically mounted on top of the spark plug. The primary voltage is measured with a direct connection via a primary lead connected to the ignition coil. Conventionally, the secondary lead clamps on a spark plug wire, however, this is not possible on newer engines with “coil-on-plug” because the coil covers the plug. Additionally, conventional secondary capacitive pickups also have circuitry built thereon to boost the secondary voltage signals. The circuits, if not working properly, can relay faulty voltage readings to the analyzer. The circuits also add additionally costs and production time to the secondary capacitive pickups. Without information regarding secondary voltage from the secondary leads, any calibration or analysis of the engine will be incorrect and incomplete. Thus it is important to obtain secondary voltage in order to proper analyze the engine and the ignition events of each cylinder.
Therefore, there is a need for a low cost apparatus and method to obtain secondary voltage in engines so that the analyzer can analyze and display accurate data, particularly one that can be used with coil-on-plug arrangements, if desired.
SUMMARY OF THE INVENTION
Embodiments of the present invention generally provide for an apparatus and method to allow the analyzer to collect secondary voltage of an ignition event. In one embodiment, a pickup apparatus for use with a lead of an analyzer that analyzes an engine having an ignition coil, the apparatus can include a first body member capable of receiving voltage signals from the ignition coil, a first attachment portion that can extend from the first body member and can attach the first body member to the ignition coil, and a first spade integral with the pickup apparatus that can extend from one of the first body member and the first attachment portion and can be connectable to the lead, wherein the first body member, the first attachment portion, and the first spade can be in communication with each other and can relay voltage signals from the ignition coil to the lead. The first body member, the first attachment portion, and the first spade can be a unitary structure and can be made from a conductive material. The conductive material may be selected from 304 stainless steel, copper, aluminum, brass, ferrous metal, and a combination thereof. The pickup apparatus can further include a second body member capable of receiving voltage signals from the ignition coil, a second attachment portion that can extend from the second body member and can attach the second body member to the ignition coil, a second spade integral with the pickup apparatus that can extend from one of the second body member and the second attachment portion and can be connectable to the lead, and a connector connecting the first and second body members, wherein the first and second body members, the first and second attachment portions, the first and second spades can be in communication with each other and can relay voltage signals from the ignition coil to the lead. The second body member and the second attachment portion can have a shape complimentary to the ignition coil to fit on the ignition coil. The first and second body members, the first and second attachment portions, and the first and second spades can be made from a conductive material. The conductive material can be 304 stainless steel, copper, aluminum, brass, ferrous metal and a combination thereof. Additionally, the first body member and the first attachment portion can have a shape complimentary to the ignition coil to fit on the ignition coil. The first and second spades can be of same thickness as the rest of the pickup apparatus and can be continuous throughout.
In another embodiment, a method of conveying signals from an ignition coil to an engine analyzer that can include attaching a secondary pickup to the ignition coil to receive signals from the ignition coil, receiving the signals from the ignition coil with the secondary pickup, and relaying the received signals to the engine analyzer. The signals may be secondary voltage signals, and the receiving step may include capacitively receiving the secondary voltage signals with the secondary pickup. The step of relaying the signals can further include the step of connecting a lead to the pickup.
In an alternative embodiment, a pickup apparatus for use with a lead of an analyzer that analyzes an engine having an ignition coil can include a first means for receiving voltage signals from the ignition coil, a first means for attaching that can extend from the means for receiving and can attach the means for receiving to the ignition coil, and a first means for connecting that can extend from one of the first means for receiving and the first means for attaching and can be connectable to the lead, wherein the first means for receiving, the first means for attaching, and the first means for connecting are in communication with each other and can relay voltage signals from the ignition coil to the lead. The first means for receiving, the first means for attaching, and the first means for connecting can be a unitary structure and can be made from a conductive material. The conductive material can be selected from 304 stainless steel, copper, aluminum, brass, ferrous metal, and a combination thereof. The pickup apparatus can further include a second means for receiving voltage signals from the ignition coil, a second means for attaching that can extend from the second means for receiving and can attach the second means for receiving to the ignition coil, a second means for connecting that can extend from one of the second means for receiving and the second means for attaching and can be connectable to the lead, and a coupling means for coupling the first and second means for receiving together, wherein the first and second means for receiving, the first and second means for attaching, and the first and second means for connecting can be in communication with each other and can relay voltage signals from the ignition coil to the lead. The second means for receiving, the second means for attaching, and the second means for connecting can be made from a conductive material that can be selected from 304 stainless steel, copper, aluminum, brass, ferrous metal, and a combination thereof.
There has thus been outlined, rather broadly, the more important features of the invention in order that the detailed description thereof that follows may be better understood, and in order that the present contribution to the art may be better appreciated. There are, of course, additional features of the invention that will be described below and which will form the subject matter of the claims appended hereto.
In this respect, before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not limited in its application to the details of construction and to the arrangements of the components set forth in the following description or illustrated in the drawings. The invention is capable of other embodiments and of being practiced and carried out in various ways. Also, it is to be understood that the phraseology and terminology employed herein, as well as the abstract, are for the purpose of description and should not be regarded as limiting.
As such, those skilled in the art will appreciate that the conception upon which this disclosure is based may readily be utilized as a basis for the designing of other structures, methods and systems for carrying out the several purposes of the present invention. It is important, therefore, that the claims be regarded as including such equivalent constructions insofar as they do not depart from the spirit and scope of the present invention.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
illustrates an analyzer with pickups according to an embodiment of the present invention.
FIGS. 2A
,
2
B and
2
C illustrate one embodiment of a secondary pickup.
FIGS. 3A
,
3
B,
3
C, and
3
D illustrate another alternative embodiment of the secondary pickup.
FIGS. 4A
,
4
B and
4
C illustrate still another alternative embodiment of the secondary pickup.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
The embodiments of the present invention provide a secondary pickup and method to measure secondary ignition patterns or secondary voltage during an ignition event. The secondary pickup can be used with an analyzer, such as an engine analyzer, and can be used with engines of varying number of cylinders (
1
,
2
,
4
, etc.).
FIG. 1
illustrates an analyzer
10
with pickups according to an embodiment of the present invention. An analyzer
10
having a first lead wire
11
connected to a primary pickup
15
and a second lead wire
12
connected to a secondary pickup
14
. The analyzer
10
can be any analyzer that receives a signal relayed by the primary pickup
15
and the secondary pickup
14
, such as an engine analyzer (VISION PREMIER™, PERCEPTION™, available from OTC, Owatonna, Minn.), a Digital Voltage Ohm Meter, a scope, a hand held meter, or other analyzers. The analyzer
10
has a microprocessor that runs the analyzer, a waveform data acquisition system that acquires waveforms, a DMA controller that controls the writing of the waveform to the memory, a memory and a user interface.
The analyzer
10
can display the primary and secondary signals on a scope in waveforms or any other format, so that the user can interpret the signals relayed by the primary
15
and secondary pickups
14
. The signals can be from the primary and secondary ignition voltage generated by an ignition coil. The ignition coil converts the low voltage (provided by a battery) to a high voltage that is routed by a distributor to the spark plug for ignition.
The analyzer
10
can be connected to various lead wires, such as the primary
11
and the secondary lead wires
12
. At a first end, the primary lead wire
11
can be connected to the analyzer
10
and at the second end to the primary pickups
15
. Since newer engines have a coil-on-plug, the primary pickup can be connected directly to the ignition coil, but a conventional secondary pickup can not be used due to the placement of the ignition coil over the spark plug.
At a first end, the secondary lead wire
12
can be connected to the analyzer
10
and at a second end to the secondary pickup
14
. The second end of the secondary lead wire
12
has a spade receiver
13
, which can mate with a spade
16
of the secondary pickup
14
. The secondary voltage signals generated from the ignition coil can be picked up by the secondary pickup
14
, travel to the spade
16
and the space receiver
13
and along the secondary lead wire
12
to the analyzer
10
. The analyzer
10
can process the secondary voltage signals and display them to the user for analysis.
The secondary pickup
14
can be made from a stamped piece of a material, such as a metal or an alloy, and can include 304 stainless steel, copper, aluminum, brass, ferrous metal, or any other conductive material. The secondary pickup
14
can be made of a material that is preferably malleable, so that its shape can be constructed and arranged to fit in a complementary fashion around a particular ignition coil.
In a preferred embodiment, the secondary pickup
14
can be custom fitted to a specific ignition coil for a particular engine so that the size and shape will provide optimal signal conduction. Ignition coils are made by various manufacturers for various car-producing companies and thus, vary in size and shape. Because the secondary pickup
14
can be custom fitted to fit a particular ignition coil, a better contact can be made leading to better conduction of the signal and better analysis of the engine cylinder. Additionally, in some embodiments, the more surface area the secondary pickup
14
has, the better the conduction of the signals.
In another embodiment, the secondary pickup
14
is also removable so that it can be removed after the engine analysis is completed. Further, the secondary pickup
14
does not contain circuits thereon, so signal errors that can result from faulty circuitry on conventional secondary pickups are avoided. Because no expensive circuitry is required on the secondary pickup
14
, the pickup is cheaper to produce and the production time can be less then conventional secondary pickups.
FIGS. 2A
,
2
B and
2
C illustrate one embodiment of a secondary pickup
20
.
FIG. 2A
is a front view illustrating the secondary pickup
20
, which can include a body
21
having at least one first member
22
, preferably at least two first members
22
, and a spade
24
. The body
21
can be any shape that fits the desired ignition coil, and preferably square or rectangular in shape and having four edges. The body
21
can fit over the top portion of the ignition coil.
The secondary members
22
extend from the body
21
along two of its four edges and can be constructed and arranged to couple with the ignition coil. The first members
22
provide additional contact areas for increased secondary voltage signal pickup and to assist in securing the secondary pickup
20
to the ignition coil. The first member
22
has a first portion
23
, a second portion
26
, and a third portion
27
. The second portion
26
is angled or truncated in relation to the first portion
23
to provide a better connection with the ignition coil.
The spade
24
connects to the spade receiver
13
of the secondary lead wire
12
to relay the secondary signals received from the ignition coil to the analyzer
10
. In one embodiment, the spade
24
can be angled from a plane of the body
21
for easier connection with the spade receiver
13
. The spade
24
can have at least a portion being hollow to receive a clip, such as an alligator type clip, preferably, the spade is solid throughout. By being solid throughout, the secondary signals are better transmitted to the spade receiver
13
through a wider continuous surface area than with a portion being hollow. Additionally, the spade
24
can have the same thickness as the rest of the secondary pickup
20
for faster production and less cost of raw materials.
In another embodiment, the spade
24
is an integral part of the secondary pickup
20
or is manufactured in one piece with the pickup, and is not required to be attached to the pickup in a separate production step. Conventional secondary pickups use connections, such as banana jacks or RCA type jacks, to connect to the secondary lead wire
12
. The banana and RCA jacks have to be soldered or welded to the pickup in a separate manufacturing process. Because the spade
24
is an integral part of the pickup
20
, the manufacturing cost and time are less then conventional pickups. Additionally, the signal is better transmitted than conventional pickups, where the signal can degrade when travelling through welded or soldered portion of the conventional pickups. Additional views of the secondary pickup
20
are also provided in the top view of FIG.
2
B and the side view of FIG.
2
C.
FIGS. 3A
,
3
B,
3
C, and
3
D illustrate another alternative embodiment of the secondary pickup
30
. In the perspective view
FIG. 3A
, the secondary pickup
30
includes a body
31
, a first member
32
and a spade
33
. The body
31
can be constructed and arranged to fit the desired ignition coil, preferably, the body is curved similarly to a complementary portion of the ignition coil. Additionally, the body
31
has a large surface contract area
36
, which contacts a significant portion of the ignition coil and helps to better conduct the secondary signals that are produced.
Extending from the body
31
is the first member
32
, which along with the spade
33
helps to secure the secondary pickup
30
to the ignition coil. The spade
33
can extend from the first member
32
or can extend from the body
31
. The first member
32
can pickup secondary voltage signals from the ignition coil.
The spade
33
is angled in relation to the body
31
to provide a better connection with the spade receiver
13
of the secondary lead wire
12
that relays the secondary voltage signals received from the ignition coil to the analyzer
10
. Additionally, the spade
33
includes a coupling portion
35
that helps to secure the secondary pickup
30
to the ignition coil. The spade
33
can have at least a portion being hollow to receive a clip, such as an alligator type clip, preferably, the spade is solid throughout. By being solid throughout, the secondary signals are better transmitted to the spade receiver
13
through a wider continuous surface area than with a portion being hollow. Additionally, the spade
33
can have the same thickness as the rest of the secondary pickup
30
for faster production and less cost of raw materials.
In another embodiment, the spade
33
is an integral part of the secondary pickup
30
or is manufactured in one piece with the pickup, and is not required to be attached to the pickup in a separate production step. Conventional secondary pickups use connections, such as banana jacks or RCA type jacks, to connect to the secondary lead wire
12
. The banana and RCA jacks have to be soldered or welded to the pickup
30
in a separate manufacturing process. Because the spade
33
is integral with the pickup
30
, the manufacturing cost and time are less then conventional pickups. Additionally, the signal is better transmitted than conventional pickups, where the signal can degrade when travelling through welded or soldered portion of the conventional pickups. Additional views of this alternative embodiment of secondary pickup
30
are also provided in the top view of
FIG. 3B
, the front view of
FIG. 3C
, and the side view of FIG.
3
D.
FIGS. 4A
,
4
B and
4
C illustrate still another alternative embodiment of the secondary pickup
40
. In one embodiment shown in
FIG. 4A
from the side, the secondary pickup
40
has a first portion
41
and a second portion
47
that are coupled together via a connecting member
45
. The first portion
41
has a first body
44
that can be constructed and arranged to fit over the desired ignition coil. At an end of the first body
44
, at least one first member
42
is present, preferably there are two first members
42
at each end of the first body. The first members
42
are constructed and arranged to help secure the secondary pickup
40
to the ignition coil. The connecting member
45
couples the first and second portions
41
,
47
together.
The second portion
47
has a second body
48
that can be constructed and arranged to fit over the desired ignition coil. The second portion
47
can be a different size than the first portion
41
. At an end of the second body
48
at least one secondary member
49
is present, preferably there are two secondary members
49
at each end of the second body. The secondary member
49
is constructed and arranged to help secure the secondary pickup
40
to the ignition coil. The secondary members
42
,
49
of the first portion
41
and the second portion
47
can also contain a spade portion
43
,
46
, respectively. In an alternative embodiment, the spade portions
43
,
46
are extends from the first and second bodies
44
,
48
.
The spade portions
43
,
46
are connected to the spade receiver
13
of the secondary lead wire
12
that relays the secondary voltage signals received from the ignition coil to the analyzer
10
. The spades
43
,
46
can have at least a portion being hollow to receive a clip, such as an alligator type clip, preferably, the spade is solid throughout. By being solid throughout, the secondary signals are better transmitted to the spade receiver
13
through a wider continuous surface area than with a portion being hollow. Additionally, the spades
43
,
46
can have the same thickness as the rest of the secondary pickup
40
for faster production and less cost of raw materials
In an other embodiment, the spade portions
43
,
46
are an integral part of the secondary pickup
30
or are manufactured in one piece with the pickup, and are not required to be attached to the pickup in a separate production step. Conventional secondary pickups use connections, such as banana jacks or RCA type jacks, to connect to the secondary lead wire
12
. The banana and RCA jacks have to be soldered or welded to the pickup
40
in a separate manufacturing process. Because the spades
43
,
46
are an integral part of the pickup
30
, the manufacturing cost and time are less then conventional pickups. Additionally, the signal is better transmitted than conventional pickups, where the signal can degrade when travelling through welded or soldered portion of the conventional pickups.
The first portion
41
and the second portion
47
are designed to fit on two different ignition coils sizes. Although it is desirous that the same model car has the same ignition coil size, it is possible that the same model may have different size ignition coils on the same engine. Additionally, the same model car may not have the same ignition coil as the previously tested model although they are the same model car. By having two different sizes of secondary pickups available, it will save the user time from searching for the correct sized secondary pickup for that model's ignition coil. Additional views of this alternative embodiment of secondary pickup
40
are also provided in the view of
FIG. 3B
, and the side of FIG.
4
C.
In an alternative embodiment, the first and second portions
41
,
47
are not connected together and are separated into individual portions. By being separated, the weight of the secondary pickup
40
is decreased, thereby saving shipping costs to the user.
The many features and advantages of the invention are apparent from the detailed specification, and thus, it is intended by the appended claims to cover all such features and advantages of the invention which fall within the true spirits and scope of the invention. Further, since numerous modifications and variations will readily occur to those skilled in the art, it is not desired to limit the invention to the exact construction and operation illustrated and described, and accordingly, all suitable modifications and equivalents may be resorted to, falling within the scope of the invention.
Claims
- 1. A pickup apparatus for use with a lead of an analyzer that analyzes an engine having an ignition coil, the apparatus comprising:a first body member capable of receiving voltage signals from the ignition coil; a first attachment portion that extends from the first body member and attaches the first body member to the ignition coil; and a first spade integral with the pickup apparatus that extends from one of the first body member and the first attachment portion and is connectable to the lead, wherein the first body member, the first attachment portion, and the first spade are in communication with each other and can relay voltage signals from the ignition coil to the lead.
- 2. The pickup apparatus of claim 1, wherein the first body member, the first attachment portion, and the first spade are a unitary structure.
- 3. The pickup apparatus of claim 1, wherein the first body member, the first attachment portion, and the first spade are made from a conductive material.
- 4. The pickup apparatus of claim 3, wherein the conductive material is selected from a group consisting of 304 stainless steel, copper, aluminum, brass, ferrous metal, and a combination thereof.
- 5. The pickup apparatus of claim 1, further comprising:a second body member capable of receiving voltage signals from the ignition coil; a second attachment portion that extends from the second body member and attaches the second body member to the ignition coil; a second spade integral with the pickup apparatus that extends from one of the second body member and the second attachment portion and is connectable to the lead; and a connector connecting the first and second body members, wherein the first and second body members, the first and second attachment portions, the first and second spades are in communication with each other and can relay voltage signals from the ignition coil to the lead.
- 6. The pickup apparatus of claim 5, wherein the second body member and the second attachment portion have a shape complimentary to the ignition coil to fit on the ignition coil.
- 7. The pickup apparatus of claim 5, wherein the first and second body members, the first and second attachment portions, and the first and second spades are made from a conductive material.
- 8. The pickup apparatus of claim 7, wherein the conductive material is selected from a group consisting of 304 stainless steel, copper, aluminum, brass, ferrous metal and a combination thereof.
- 9. The pickup apparatus of claim 1, wherein the first body member and the first attachment portion have a shape complimentary to the ignition coil to fit on the ignition coil.
- 10. The pickup apparatus of claim 5, wherein the first and second spades are of same thickness as the rest of the pickup apparatus.
- 11. The pickup apparatus of claim 5, wherein the first and second spades are continuous throughout.
- 12. A method of conveying signals from an ignition coil to an engine analyzer, comprising:attaching a secondary pickup to the ignition coil to receive signals from the ignition coil; receiving the signals from the ignition coil with the secondary pickup; and relaying the received signals to the engine analyzer.
- 13. The method of claim 12, wherein the signals are secondary voltage signals, and the receiving step comprises capacitively receiving the secondary voltage signals with the secondary pickup.
- 14. A method according to claim 12, wherein the step of relaying the signals further comprises the step of connecting a lead to the pickup.
- 15. A pickup apparatus for use with a lead of an analyzer that analyzes an engine having an ignition coil, the apparatus comprising:a first means for receiving voltage signals from the ignition coil; a first means for attaching that extends from the means for receiving and attaches the means for receiving to the ignition coil; and a first means for connecting that extends from one of the first means for receiving and the first means for attaching and is connectable to the lead, wherein the first means for receiving, the first means for attaching, and the first means for connecting are in communication with each other and can relay voltage signals from the ignition coil to the lead.
- 16. The pickup apparatus of claim 15, wherein the first means for receiving, the first means for attaching, and the first means for connecting are a unitary structure.
- 17. The pickup apparatus of claim 15, wherein the first means for receiving, the first means for attaching, and the first means for connecting are made from a conductive material.
- 18. The pickup apparatus of claim 17, wherein the conductive material is selected from a group consisting of 304 stainless steel, copper, aluminum, brass, ferrous metal, and a combination thereof.
- 19. The pickup apparatus of claim 15, further comprising:a second means for receiving voltage signals from the ignition coil; a second means for attaching that extends from the second means for receiving and attaches the second means for receiving to the ignition coil; a second means for connecting that extends from one of the second means for receiving and the second means for attaching and is connectable to the lead; and a coupling means for coupling the first and second means for receiving together, wherein the first and second means for receiving, the first and second means for attaching, and the first and second means for connecting are in communication with each other and can relay voltage signals from the ignition coil to the lead.
- 20. The pickup apparatus of claim 19, wherein the second means for receiving, the second means for attaching, and the second means for connecting are made from a conductive material.
- 21. The pickup apparatus of claim 20, wherein the conductive material is selected from a group consisting of 304 stainless steel, copper, aluminum, brass, ferrous metal, and a combination thereof.
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A |
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A |
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A |
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