AU616220B2 - Creación de Inventos y Patentes con Inteligencia Artificial

AU616220B2 – Improved magnetic sensing proximity detector
– Google Patents

AU616220B2 – Improved magnetic sensing proximity detector
– Google Patents
Improved magnetic sensing proximity detector

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Info

Publication number
AU616220B2

AU616220B2
AU25604/88A
AU2560488A
AU616220B2
AU 616220 B2
AU616220 B2
AU 616220B2
AU 25604/88 A
AU25604/88 A
AU 25604/88A
AU 2560488 A
AU2560488 A
AU 2560488A
AU 616220 B2
AU616220 B2
AU 616220B2
Authority
AU
Australia
Prior art keywords
magnet
housing
movable
proximity detector
magnets
Prior art date
1987-12-08
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Ceased

Application number
AU25604/88A
Other versions

AU2560488A
(en

Inventor
Gerald S. Baker
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Cameron International Corp

Original Assignee
Cameron Iron Works Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
1987-12-08
Filing date
1988-11-16
Publication date
1991-10-24

1988-11-16
Application filed by Cameron Iron Works Inc
filed
Critical
Cameron Iron Works Inc

1989-06-15
Publication of AU2560488A
publication
Critical
patent/AU2560488A/en

1991-10-24
Application granted
granted
Critical

1991-10-24
Publication of AU616220B2
publication
Critical
patent/AU616220B2/en

1995-08-17
Assigned to COOPER CAMERON CORPORATION
reassignment
COOPER CAMERON CORPORATION
Alteration of Name(s) in Register under S187
Assignors: CAMERON IRON WORKS USA, INC.

2008-11-16
Anticipated expiration
legal-status
Critical

Status
Ceased
legal-status
Critical
Current

Links

Espacenet

Global Dossier

Discuss

Classifications

H—ELECTRICITY

H01—ELECTRIC ELEMENTS

H01H—ELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES

H01H36/00—Switches actuated by change of magnetic field or of electric field, e.g. by change of relative position of magnet and switch, by shielding

H01H36/008—Change of magnetic field wherein the magnet and switch are fixed, e.g. by shielding or relative movements of armature

Abstract

The improved magnetic proximity detector of the present invention includes a tubular housing (12), a tubular magnet (14) fixed in position within the housing, a first movable magnet (18) within said housing at one end of said tubular magnet, a second movable magnet (20) within the housing at the other end of the tubular magnet, an annular magnet (38) positioned in surrounding relationship to the housing, means (40, 42) for adjusting the position of the annular magnet axially with respect to said housing, means (22) connecting the first movable magnet and the second movable magnet, a switch including a blade (28), a first contact (24) and a second contact (26), and means connecting said first and second movable magnets to said blade so that movement of said first and second movable magnets moves said blade between contact with the first and second contacts. The first movable magnet (18) has its poles arranged so that it is attracted to said tubular magnet and the second movable magnet has its poles arranged so that it is repelled by the tubular magnet, the nearness of a ferrous metal (46) to the end of said housing containing said first magnet moving the two magnets and the blade to change the position of the switch, and the adjusting of the position of said annular magnet changing the flux from the end of the housing containing the first magnet to adjust the distance at which a ferrous metal causes the change of position of the switch blade.

Description

AUSTRALIA
Patents Act 616220 CWLETE SPECIFICATIN
(ORIGINAL)
Class I:nt. Class Application Number: Lodged: Complete Specification Lodged: Accepted: Published: Priority 0040 044~0 4400 000.
0 04 4 04 0 0 04 o 00 0 o 00 o 00 000004 000400 O 0 0 00 00 0 000000 4 4 Related Art: APPLICANT’S REFERENCE: 4-167(B) CVE-339 Name(s) of Applicant(s): Cameron Iron Works Inc Address(es) of Applicant(s): 13013 Northwest Freeway, Houston, Texas, UNITED STATES OF AMERICA.
Address for Service is: PHILLIPS ORDMtNDE FITZPA
T
RICK
Patent and Trade Mark Attorneys 367 Collins Street Melbourne 3000 AUSTRALIA Complete Specification for the invention entitled: IM~PROAVED MANWETIC SENSINGK P1CXIMITY DETECTOR Our Ref 112373 POF Code: 1048/53122 The following statement is a full description of this invention, including the best method of performing it known to applicant(s): 6003q/ 1 1-
‘K
ij
P
2 4-167 CVE-339 IMPROVED MAGNETIC SENSING PROXIMITY DETECTOR The present invention relates to an improved magnetic sensing proximity detector. Magnetic sensing proximity detectors have been used previously to detect the close presence of a ferrous metal mass. In one form these detectors have includes a central hollow magnet with end magnets supported on a rod connecting them which rc 0 t Pextends through the opening in the central magnet. A switch is connected at one end of the oo two connected magnets to be operated by the movement of such two magnets relative to the central magnet and the housing in which it is secured. The approach of a ferrous metal close 15 to the end of the magnet away from the switch end .causes the magnets and their connecting rod to move toward the ferrous metal to thus change the position of the switch. An example of this type of magnetic sensing proximity switch is disclosed in U. S. Patent No. 4,117,431.
So Another type of magnetic sensing proximity o detector is shown in U. S. Patent No. 4,674,338 in which a central magnet is positioned within two annular magnets so that the movement of the i central magnet which is normally biased in one dire-ction by the positioning of the poles of the three magnets, moves in the opposite direction when a magnetic material approaches sufficiently close to change the forces on the central magnet i~rl- e 1- i -3to overcome the force biasing it toward the one direction.
A further type of magnetic sensing proximity detector is shown in U. S. Patent Nos. 3,176,096 and 4,225,837 wherein side-by-side magnets are used so that the position of the switch arm is normally in one position and pivots to the opposite position on the approach of a ferrous metal within the range of sensitivity of the detector. The latter patent is stated to be an improvement on the former patent.
tOne disadvantage which has been experienced with the prior magnetic sensing proximity t, detectors is their very limited range in which they can sense the approach a ferrous metal «f material and the fact that such prior devices are not adjustable to preselect the exact point at which the approach of ferrous metal causes the detector to change its position.
S KmarY 4. The improved magnetic proximity de ctor includes a tubular housing, a tubular magnet fixed in position within the housipg, a first movable magnet within said housing-/at one end of said tubular magnet, a second movable magnet within the housing at th other end of the S0 tubular magnet, an annar magnet positioned in surrounding relatio’ip to the housing, means for adjusting the/position of the annular magnet to control the sensitivity of the assembly, means conneting the first magnet and the second magnet ,a switch including a blade, a first conact and a second contact, means connecting A r-r,,t an 4r An object of the present invention is to provide an improved magnetic proximity det.ctor which has increased range of sensitivity to ferrous metal.
A further object is to provide an improved magnetic proximity detector which has an adjustable range of sensitivity to ferrous metals.
The present invention provides a magnetic proximity detector for ferrous metals comprising a housing, an assembly of magnets, at least one of which is movable, positioned within said housing, a switch, means connecting the movable magnet to the switch to change its position when the magnet moves, said movable magnet being biased to one position by the other magnets of said assembly and moving to its other position responsive to the presence of a ferrous metal within its effective sensitivity range, and means for focusing the flux of said magnets to change the effective sensitivity range for movement of said movable magnet responsive to the presence of a ferrous S metal.
cede 120 The following description refers in more detail to the various features of the magnetic proximity detector of Sthe present invention. To facilitate an understanding of o the invention, reference is made in the description to the accompanying drawings where the magnetic proximity detector is illustrated in a preferred embodiment. It is o:o to be understood that the magnetic proximity detector of the present invention is not limited to the preferred o embodiment as illustrated in the drawings.
FIGURE 1 is a longitudinal sectional view of the .30 improved magnetic proximity detector illustrating the components in one position which does not indicate the presence of ferrous metal.
FIGURE 2 is a similar sectional view of the detector but showing the components in their ph )39 -4- ;i 1 CL–~III- -iii:: 11–1 i .x opposite position as a result of the detections of a ferrous metal.
FIGURE 3 is a schematic view of the three magnets used with proximity detectors of the prior art and illustrates the relative position of the poles of the magnets and their flux fields.
FIGURE 4 is a schematic view of the three magnets used in the detector of the present invention and illustrates the relative position of the poles of the magnets, their flux fields Sand the focusing effect on the flux field at the end of the detector resulting from the annular t focusing magnet.
E i CQ f t I E t. IThe improved structure of the present invention is shown in FIGURES 1 and 2. Detector includes housing 12, tubular magnet 14 secured within housing 12, assembly 16 of movable magnets, and switch contacts 24 and 26 and blade 28. Movable magnet 18 is positioned in end 29 of housing 12 and has its poles arranged with S» respect to the poles of tubular magnet 14, as shown, so that it is attracted by tubular magnet 14. Movable magnet 20 is positioned within housing 12 on the opposite side of tubular magnet 0 0 14 from magnet 18 and has its poles arranged with respect to the poles of tubular magnet 14, as shown, so that it is repelled by tubular magnet 14. A suitable non-magnetic closure 29a is positioned across end 29 of housing 12.
Connecting means 22 includes rod extending through the central axial opening of tubular magnet 14 with support by low friction i
A/
NIS
‘i’ N L c, r.3 :it *18 -6plastic bearings 32 and 34 which are positioned in the ends of the axial opening through tubular magnet 14 as shown. One end of rod 30 is connected to movable magnet 18 and the other end is connected to movable magnet 20. Extension 36 connects to movable magnet 20 and is secured to blade 28 which is pivotally mounted to contact 37 so that movement of magnet assembly 16 moves blade 28 between positions engaging contacts 24 and 26. In the position shown in FIGURE 1 blade 28 connects contact 37 with contact 26.
o00 Annular magnet 38 is positioned around the ooo0 o0000 exterior of housing 12 generally at a position surrounding movable magnet 18. Nuts 40 and 42 oo0 15 are threaded onto threads 44 on the exterior of S 00o 00 .o housing 12 on either side of annular magnet 38 to to Sosecure it in a preselected position with respect to movable magnet 18. Nuts 40 and 42, or other :suitable adjustable positioning means, are used ‘t 20 to adjust the position of annular magnet 38 which ,o0 adjusts the range of sensitivity of the structure as hereinafter explained. As shown in FIGURE *g00000 0 E 1 movable magnet assembly is in its right 000000 °ooo position with blade 28 in engagement with 25 contact 26 since ferrous mass 46 is spaced PA0 0outside the sensitivity range of detector os o Mass 48, shown in FIGURE 2, is positioned closer to detector 10 so that is within the sensitivity range, considering the position of annular magnet 38 and assembly 16 has been moved to its left causing blade 28 to move into engagement with contact 24 to complete the circuit between contact 37 and contact 24. It should be noted that annular magnet 38 is shown o -7including pole pieces 38a and 38b but may be used without such pole pieces.
I Dashed line 49 in FIGURE 3 illustraties the outer limit of the sensitivity range for detector 10 when annular magnet is not used with detector Detector 50 shown in FIGURE 3 is Sillustrative of the prior art detectors.
SDetector 50 includes movable magnet 52, fixed tubular magnet 54 and movable magnet 56 controlling the position of blade 58. Detector does not include an external annular magnet for focusing the flux field as hereinafter described. With detector 50 as shown in FIGURE 3, the sensitivity range is limited to a maximum of 0.10 inch.
c FIGURE 4 is a schematic illustration of c proximity detector 110 which is the same structure as detector 10 previously described and j the components shown are given the same number 20 for identification with the prefix numeral A comparison of the flux field of movable magnet 118 with the flux field of movable magnet 52 Sillustrates the focusing effect of annular magnet
C
C 138 on the flux field to flatten the field and cause it to extend a greater distance beyond the i end of magnet 118 than it would extend without annular magnet 138. Dashed line 149 is drawn in position with respect to the end of the housing i to illustrate the outer limit of the sensitivity range of detector 110. In comparison the the maximum range of sensitivity of detector 50 being 0.10 inch, the maximum range of sensitivity for detector 110 having all of the same components as detector 50 except for the addition of annular of annula i-! II mn~
~I
3 -8focusing magnet 138 is approximately 0.50 inch.
Additionally, the adjusting of the position of annular focusing magnet 138 provides an adjustment of the focusing of the flux field of movable magnet 118 to preselect the exact distance at which a ferrous metal will cause a change in the position of blade 128.
It should be noted the present invention has application to other types of magnetic proximity sensing devices, particularly to a device which includes at least three magnets with at least one magnet movable with respect two fixed magnets in a housing as discloses in U. S. Patent No.
4,674,338.
‘C
r t tL ~C C; I C CP ECr C CC C 0 i -e

Claims (4)

2. A magnetic proximity detector according to claim 1 wherein, one of said magnets of said C C E assembly is fixed within said housing and two of e said magnets are movable with respect to said fixed magnet, and means for connective the two CC C 4CC movable magnets. C A magnetic proximity detector according to claim 2 wherein, said fixed magnet is tubular with a central opening therethrough, and said Cconnecting means extends through the central opening with a movable magnet positioned within the housing on each end of said fixed magnet.

4. A magnetic proximity detector according to claim 1 wherein said focusing means includes an annular magnet surrounding said housing. A magnetic proximity detector according to claim 4 including means coacting with said i I annular magnet to adjust its position axially with respect to said housing.

6. A magnetic proximity detector according to claim 5 wherein, said housing includes threads along its exterior, and said adjusting means includes at least one member threaded to the exterior of said housing and held against said annular magnet. )J 7. A magnetic proximity detector according to claim 6 wherein said adjusting means includes |a first nut threaded onto said external housing threads, and a second nut threaded onto said S external housing threads, said annular magnet C 0 being positioned between said first and second i c nuts. cc 4 8. A magnetic proximity detector according c* to claim 2 wherein one of said movable magnets is positioned within said housing at one end of e’c said fixed magnet and has its poles arranged with c, respect to the poles of the fixed magnet so that it is attracted to the fixed magnet, the other of said movable magnets is positioned within said housing at the other end of said fixed magnet and has its poles arranged with respect to the poles 00 of the fixed magnet so that it is repelled by the t fixed magnet, the position of said movable magnets being biased in one direction when not presence of the movable magnets moving fro said i biased position toward the ferrous m:etal which comes within the effective range sensitivity of the detector to the ferrous etal. DATED: 15 November 198:.:; PHILLIPS ORMONDE F TZPATRICK Attorneys for: CAMERON IRON WORKS USA, INC. .4. detecting the presence of a ferrous metal and the movable magnets moving from said biased position toward a ferrous metal which comes within the effective range of sensitivity of the detector to the ferrous metal.

9. A magnetic proximity detector according to claim 1 substantially as hereinbefore described with reference to the accompanying drawings. Dated: 8 August 1991 PHILLIPS ORMONDE FITZPATRICK Attorneys for: CAMERON IRON WORKS USA, INC. ri 000 0 0 39 1* LSw -t tu LS-1).

AU25604/88A
1987-12-08
1988-11-16
Improved magnetic sensing proximity detector

Ceased

AU616220B2
(en)

Applications Claiming Priority (2)

Application Number
Priority Date
Filing Date
Title

US130242

1987-12-08

US07/130,242

US4837539A
(en)

1987-12-08
1987-12-08
Magnetic sensing proximity detector

Publications (2)

Publication Number
Publication Date

AU2560488A

AU2560488A
(en)

1989-06-15

AU616220B2
true

AU616220B2
(en)

1991-10-24

Family
ID=22443744
Family Applications (1)

Application Number
Title
Priority Date
Filing Date

AU25604/88A
Ceased

AU616220B2
(en)

1987-12-08
1988-11-16
Improved magnetic sensing proximity detector

Country Status (8)

Country
Link

US
(1)

US4837539A
(en)

EP
(1)

EP0320112B1
(en)

JP
(1)

JPH01186725A
(en)

AT
(1)

ATE120880T1
(en)

AU
(1)

AU616220B2
(en)

CA
(1)

CA1304469C
(en)

DE
(1)

DE3853516T2
(en)

NO
(1)

NO885433L
(en)

Families Citing this family (56)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US4999599A
(en)

1990-04-20
1991-03-12
Irvin Automotive Products, Inc.
Magnetic switch and latch for vehicle accessories

WO1994025944A1
(en)

1993-04-30
1994-11-10
A & H International Products
Proximity monitoring apparatus employing encoded, sequentially generated, mutually orthogonally polarized magnetic fields

US6329895B1
(en)

1995-11-14
2001-12-11
Albert Maurer
Releasing magnet for anti-theft devices for sales goods

US5929731A
(en)

1996-05-08
1999-07-27
Jackson Research, Inc.
Balanced magnetic proximity switch assembly

US5877664A
(en)

1996-05-08
1999-03-02
Jackson, Jr.; John T.
Magnetic proximity switch system

US5880659A
(en)

1997-03-17
1999-03-09
Woods; Randell
Magnetic switch assembly for detecting unauthorized opening of doors or windows

US6087936A
(en)

1998-12-29
2000-07-11
Woods; Randall
Vibration sensor

US6670805B1
(en)

2000-09-22
2003-12-30
Alliant Techsystems Inc.
Displacement sensor containing magnetic field sensing element between a pair of biased magnets movable as a unit

US6538542B2
(en)

2001-01-25
2003-03-25
Sagami Electric Co., Ltd.
Magnetic sensor switch

US7489217B2
(en)

2007-04-24
2009-02-10
Rohrig Iii Vincent W
Magnetic proximity sensor

US7936242B2
(en)

2007-09-14
2011-05-03
William N Carpenter
Magnetically operated electrical switch

US9105380B2
(en)

2008-04-04
2015-08-11
Correlated Magnetics Research, Llc.
Magnetic attachment system

US7800471B2
(en)

2008-04-04
2010-09-21
Cedar Ridge Research, Llc
Field emission system and method

US8279032B1
(en)

2011-03-24
2012-10-02
Correlated Magnetics Research, Llc.
System for detachment of correlated magnetic structures

US8179219B2
(en)

2008-04-04
2012-05-15
Correlated Magnetics Research, Llc
Field emission system and method

US8779879B2
(en)

2008-04-04
2014-07-15
Correlated Magnetics Research LLC
System and method for positioning a multi-pole magnetic structure

US9371923B2
(en)

2008-04-04
2016-06-21
Correlated Magnetics Research, Llc
Magnetic valve assembly

US9202616B2
(en)

2009-06-02
2015-12-01
Correlated Magnetics Research, Llc
Intelligent magnetic system

US8760250B2
(en)

2009-06-02
2014-06-24
Correlated Magnetics Rsearch, LLC.
System and method for energy generation

US8816805B2
(en)

2008-04-04
2014-08-26
Correlated Magnetics Research, Llc.
Magnetic structure production

US8368495B2
(en)

2008-04-04
2013-02-05
Correlated Magnetics Research LLC
System and method for defining magnetic structures

US8576036B2
(en)

2010-12-10
2013-11-05
Correlated Magnetics Research, Llc
System and method for affecting flux of multi-pole magnetic structures

US8760251B2
(en)

2010-09-27
2014-06-24
Correlated Magnetics Research, Llc
System and method for producing stacked field emission structures

US8373527B2
(en)

2008-04-04
2013-02-12
Correlated Magnetics Research, Llc
Magnetic attachment system

US8174347B2
(en)

2010-07-12
2012-05-08
Correlated Magnetics Research, Llc
Multilevel correlated magnetic system and method for using the same

US8917154B2
(en)

2012-12-10
2014-12-23
Correlated Magnetics Research, Llc.
System for concentrating magnetic flux

US8937521B2
(en)

2012-12-10
2015-01-20
Correlated Magnetics Research, Llc.
System for concentrating magnetic flux of a multi-pole magnetic structure

US9275783B2
(en)

2012-10-15
2016-03-01
Correlated Magnetics Research, Llc.
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US8704626B2
(en)

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Correlated Magnetics Research, Llc
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(en)

2012-08-06
2016-02-09
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US9404776B2
(en)

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2016-08-02
Correlated Magnetics Research, Llc.
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US9711268B2
(en)

2009-09-22
2017-07-18
Correlated Magnetics Research, Llc
System and method for tailoring magnetic forces

WO2011037845A2
(en)

2009-09-22
2011-03-31
Cedar Ridge Research, Llc.
Multilevel correlated magnetic system and method for using same

US8400241B2
(en)

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2013-03-19
General Equipment And Manufacturing Company, Inc.
Magnetically-triggered proximity switch

CA2801181C
(en)

2010-06-11
2018-05-01
General Equipment And Manufacturing Company, Inc., D/B/A Topworx, Inc.
Magnetically-triggered proximity switch

US8638016B2
(en)

2010-09-17
2014-01-28
Correlated Magnetics Research, Llc
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JP2012163512A
(en)

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Mohammad Sarai
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US8963380B2
(en)

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2015-02-24
Correlated Magnetics Research LLC.
System and method for power generation system

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(en)

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2015-12-22
Correlated Magnetics Research, Llc
Magnetic shear force transfer device

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2014-09-30
Correlated Magnetics Research LLC
System and method for authenticating an optical pattern

CN103295836B
(en)

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2017-10-31
通用设备和制造公司
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(en)

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2013-11-27
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EP2820659A4
(en)

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2016-04-13
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DE102012104412A1
(en)

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2013-11-28
Endress + Hauser Conducta Gesellschaft für Mess- und Regeltechnik mbH + Co. KG

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US9245677B2
(en)

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Correlated Magnetics Research, Llc.
System for concentrating and controlling magnetic flux of a multi-pole magnetic structure

US9298281B2
(en)

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2016-03-29
Correlated Magnetics Research, Llc.
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US9202650B2
(en)

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2015-12-01
General Equipment And Manufacturing Company, Inc.
Quick disconnect connector assembly

US9355800B2
(en)

2013-09-13
2016-05-31
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CN103594285B
(en)

2013-10-12
2015-12-23
广东广益科技实业有限公司
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CN104008917B
(en)

2014-06-17
2016-01-20
佛山市川东磁电股份有限公司
A kind of magnetic approach switch

US9754743B1
(en)

2016-03-02
2017-09-05
General Equipment And Manufacturing Company, Inc.
Actuation apparatus for magnetically-triggered proximity switches

GB2607789A
(en)

2020-01-24
2022-12-14
General Equipment And Mfg Company Inc D/B/A Topworx Inc
High temperature switch apparatus

GB2588568B
(en)

2021-02-09
2021-11-03
Longvale Ltd
Sensor assemblies

WO2022171975A1
(en)

2021-02-09
2022-08-18
Longvale Ltd
Sensor assemblies

Citations (2)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US4117431A
(en)

1977-06-13
1978-09-26

General Equipment & Manufacturing Co., Inc.

Magnetic proximity device

US4674338A
(en)

1984-12-31
1987-06-23

Lake Charles Instruments, Inc.

Flow volume detection device

Family Cites Families (8)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US3176096A
(en)

1961-12-26
1965-03-30
Gen Equipment & Mfg Company In
Magnetic proximity-sensing devices

US3373383A
(en)

1965-02-02
1968-03-12
Shoichi Shimada
Automatic current limiting circuit breaker

US3390362A
(en)

1965-10-23
1968-06-25
Raymond W. Hoeppel
Polarized sensitive circuit breaker utilizing a magnetic reed switch

US3402376A
(en)

1965-11-15
1968-09-17
William P. Gardiner
Switch with magnetically controlled inner rotating and reciprocating element

GB1469571A
(en)

1974-12-23
1977-04-06
Mettoy Co Ltd
Reed contact units

US4225837A
(en)

1978-12-28
1980-09-30
General Equipment & Mfg. Co., Inc.
Armature for a proximity switch

US4414518A
(en)

1980-10-16
1983-11-08
Abex Corporation
Vertical descent rate detector switch

US4596971A
(en)

1984-07-26
1986-06-24
Tdk Corporation
Magnetic circuit device

1987

1987-12-08
US
US07/130,242
patent/US4837539A/en
not_active
Expired – Fee Related

1988

1988-11-03
DE
DE3853516T
patent/DE3853516T2/en
not_active
Expired – Fee Related

1988-11-03
AT
AT88310350T
patent/ATE120880T1/en
not_active
IP Right Cessation

1988-11-03
EP
EP88310350A
patent/EP0320112B1/en
not_active
Expired – Lifetime

1988-11-10
CA
CA000582718A
patent/CA1304469C/en
not_active
Expired – Fee Related

1988-11-16
AU
AU25604/88A
patent/AU616220B2/en
not_active
Ceased

1988-12-02
JP
JP63305886A
patent/JPH01186725A/en
active
Pending

1988-12-07
NO
NO88885433A
patent/NO885433L/en
unknown

Patent Citations (2)

* Cited by examiner, † Cited by third party

Publication number
Priority date
Publication date
Assignee
Title

US4117431A
(en)

1977-06-13
1978-09-26
General Equipment & Manufacturing Co., Inc.
Magnetic proximity device

US4674338A
(en)

1984-12-31
1987-06-23
Lake Charles Instruments, Inc.
Flow volume detection device

Also Published As

Publication number
Publication date

ATE120880T1
(en)

1995-04-15

CA1304469C
(en)

1992-06-30

EP0320112A3
(en)

1990-09-12

EP0320112B1
(en)

1995-04-05

NO885433L
(en)

1989-06-09

US4837539A
(en)

1989-06-06

DE3853516D1
(en)

1995-05-11

DE3853516T2
(en)

1995-08-17

EP0320112A2
(en)

1989-06-14

AU2560488A
(en)

1989-06-15

JPH01186725A
(en)

1989-07-26

NO885433D0
(en)

1988-12-07

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