Bi-stable battery switch

CROSS REFERENCES TO CO-PENDING APPLICATIONS

None.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention is for a battery switch, and more particularly, pertains to a bi-stable battery switch incorporated preferably for internal use into a remotely switchable storage battery, or, in the alternative, for external use with a battery.

2. Description of the Prior Art

Remotely switchable storage batteries, such as for use in, but not limited to, an automobile, have been offered for use as an anti-theft deterrent. A switch is contained in a battery and is operated remotely by a small hand-held remote transmitting device. An individual merely activates the remote transmitting device whereby a receiver located in the battery case is activated to trigger the disconnection of the battery circuit internally within the battery case, thereby removing available battery power to the circuits residing in the automobile such as, for example, and which may be highly inductive loads, ignition modules, starters, generators, alternators, fans and the like. Such disconnection electrically disables the automobile, or other vehicle in which the remotely switchable storage battery is installed. Often, operators of the vehicle would decide to remotely shut down and disable the vehicle with the vehicle still running as an alternative to first turning off the vehicle. Using this method, high inductive loads are still operative at the instant of remote electrical disablement. In the presence of the high inductive loads during remote shutdown, prior art switching methods, particularly with respect to the electrical switching contacts, caused excessive arcing across the switching contacts during shutdown. Excessive arcing across breaking or making electrical contacts is an undesirable trait present when breaking or making an inductive load and often causes premature degradation of the surfaces of the electrical contacts, thereby causing contact or switch failure. Remote reconnection and enabling of the remotely switchable storage battery provides an imposition of inductive loads across the switch contacts, also causing undesirable contact arcing leading to premature failure of the contacts.

Clearly what is needed is a switching device which overcomes the flaws and deficiencies of the prior art.

SUMMARY OF THE INVENTION

The general purpose of the present invention is a bi-stable battery switch for incorporation into or about a remotely switchable storage battery. The bi-stable battery switch in general is a double bar bus switch in which a solenoid pulses a cam which in turn actuates or de-actuates two parallel circuit spring loaded positionable bus bars comprising a bifurcated contact assembly to either break or make an electrical connection across adjacent and aligned stationary and wide V-shaped contacts located on switch terminals. Each of the positionable bus bars is cam operated or influenced and is in the form of a movable bar having two contacts located thereupon, each contact having an arced surface. During the making of an electrical contact to connect the battery to the electrical system of an automobile, the direct influence of a cam is eliminated to allow spring forces to urge the two spring loaded positionable bus bars of the bifurcated contact assembly into near simultaneous dual contact with and across the wide stationary V-shaped contacts of the switch terminals. Although both positionable bus bars are springingly and simultaneously urged toward and into intimate dual contact with the stationary and wide contacts located on the switch terminals, one positionable bus bar precedes, in a very short time span, the adjoining positionable bus bar and picks up the arcing load in contacting the wide contacts of the switch terminals only to be closely followed by the remaining positionable bus bar which in contacting the wide contacts of the switch terminals picks up the current load.

According to one or more embodiments of the present invention there is provided a bi-stable battery switch for use with and for incorporation into internal use with a remotely switchable storage battery, or, in the alternative, for external use with a battery. The bi-stable battery switch is built about and within a substantially rectangular enclosure having a top and a bottom to which components align and secure. Located in the rectangular enclosure is a vertically aligned cam and associated members which are actuated by a cam driver arm connected to the solenoid core. Adjacent to the vertically aligned cam is a bifurcated contact assembly having two spring loaded positionable bus bars which are aligned to and actuated by the vertically aligned cam. A large switch terminal and a small switch terminal, each having wide V-shaped contacts which are sized to contact the arc-shaped contacts on both positionable bus bars, align to the bifurcated contact assembly to either make or break contacts thereupon.

One significant aspect and feature of the present invention is a bi-stable battery switch which exhibits a long life.

Another significant aspect and feature of the present invention is a bi-stable battery switch having a bifurcated contact assembly having an upper and a lower bus bar.

Still another significant aspect and feature of the present invention is a bi-stable battery switch where a cam arrangement is used in pulse fashion to cause advancing or retarding of a bifurcated contact assembly.

Yet another significant aspect and feature of the present invention is the incorporation of upper and lower bus bars whereby inductive loads are distributed along both the upper and lower bus bars. In making of the contacts, the first to accept an inductive load accepts an arcing load while the second to accept an inductive load accepts a current load; while in breaking of the contacts, the first to shed an inductive load sheds a current load and the second to shed an inductive load sheds an arcing load.

Having thus described an embodiment of the present invention and specified significant aspects and features thereof, it is the principal object of the present invention to provide a bi-stable battery switch.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects of the present invention and many of the attendant advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, in which like reference numerals designate like parts throughout the figures thereof and wherein:

FIG. 1

illustrates an isometric view of a bi-stable battery switch, the present invention;

FIG. 2

illustrates an exploded isometric view of the bi-stable battery switch;

FIG. 3

illustrates an isometric view of the small switch terminal;

FIG. 4

illustrates an isometric view of the large switch terminal;

FIG. 5

illustrates an isometric view of the upper bus bar and a contact guide;

FIG. 6

illustrates an isometric view of the enclosure bottom;

FIG. 7

illustrates an inverted isometric view of the enclosure top;

FIG. 8

illustrates an inverted isometric view of the cam driver;

FIG. 9

illustrates an isometric view of the carrier driver;

FIG. 10

illustrates an inverted isometric view of the cam;

FIGS. 11-14

, each illustrates a partial side view in perspective of the bi-stable battery switch where the enclosure bottom, the large switch terminal and other members have been removed for the purpose of clarity and brevity. Addition of member elements associated with a cam and actuation thereof is progressively shown throughout

FIGS. 11-14

;

FIGS. 15 and 16

illustrate a cross sectional top view through the large switch terminal U-shaped structure of the bi-stable battery switch where the enclosure top has been removed and where a portion of the horizontally oriented planar structure of the large switch terminal is shown in dashed lines. Also shown is the relationship of the vertically oriented cam which either intimately engages, urges and forces movement of the bifurcated contact assembly to interrupt electrical contact or which is withdrawn from intimate contact with the bifurcated contact assembly to allow spring forces to urge and force the bifurcated contact assembly into electrical contact across contacts of the switch; and,

FIG. 17

illustrates the incorporation of the present invention, the bi-stable battery switch, into the top portion of a storage battery such as used in an automobile or in a variety of other objects.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1

illustrates an isometric view of a bi-stable battery switch

10

, the present invention. Visible in the illustration is a rectangular enclosure bottom

12

mated with a substantially planar enclosure top

14

, a clip

15

extending between and securing one end of the enclosure top

14

to one end of the enclosure bottom

12

, a solenoid

16

mated and attached to one end of the enclosure top

14

and one end of the enclosure bottom

12

and securing them together, a large configured switch terminal

20

located over and about the solenoid

16

and a portion of the enclosure top

14

and extending both downwardly and inwardly to a location between the enclosure top

14

and the enclosure bottom

12

, a small configured switch terminal

18

in opposition to the large switch terminal

20

extending downwardly and inwardly to a location between the enclosure top

14

and the enclosure bottom

12

, and, attachment holes

22

and

24

located at the ends of the small switch terminal

18

and the large switch terminal

20

, respectively.

FIG. 2

illustrates an exploded isometric view of the bi-stable battery switch

10

, where all numerals previously mentioned correspond to those elements previously described. With reference to FIG.

2

and with implied reference to other figures showing the invention, components of the bi-stable battery switch

10

and their relationship is now described. The small switch terminal

18

, also shown in

FIG. 3

, includes a horizontally oriented planar structure

18

a

, a vertically oriented planar structure

18

b

extending downwardly from horizontally oriented planar structure

18

a

, and a planar contact mounting pad

18

c

extending at a right angle and inwardly from the vertically oriented planar structure

18

b

. A dual and continuous contact

26

having juxtaposed wide V-shaped contact surface arrangements (

FIG. 3

) secures to one side of the contact mounting pad

18

c

. Correspondingly, the large switch terminal

20

, also shown in

FIG. 4

, includes a horizontally oriented planar structure

20

a

, a small vertically oriented planar structure

20

b

extending upwardly from the horizontally oriented planar structure

20

a

, a horizontally oriented planar structure

20

c

extending horizontally from the vertically oriented planar structure

20

b

, a U-shaped structure

20

d

extending downwardly from the horizontally oriented planar structure

20

c

, a vertically oriented planar structure

20

e

extending downwardly from the U-shaped structure

20

d

, and a planar contact mounting pad

20

f

(

FIG. 4

) extending at a right angle and inwardly from the vertically oriented planar structure

20

e

. A dual and continuous contact

28

having juxtaposed wide V-shaped contact surface arrangements (

FIG. 4

) secures to one side of the contact mounting pad

20

f.

Located in close proximity and alignment to the contacts

26

and

28

is a bifurcated contact assembly

30

having identical but mutually inverted and opposing spring loaded positionable upper and lower bus bars

32

and

34

located in close proximity and alignment for contacting of the contacts

26

and

28

. As shown in

FIG. 5

, the upper bus bar

32

, and thus also the identical lower bus bar

34

, includes opposing arc-shaped contacts

36

and

38

, a cam surface

40

disposed vertically between the opposing arc-shaped contacts

36

and

38

, and, a guide bar

42

located on a planar surface

44

and at a right angle to the cam surface

40

. Upper and lower channel-shaped contact guides

46

and

48

interface between the upper and lower bus bars

32

and

34

and the enclosure top

14

and the enclosure bottom

12

, respectively, as later described in detail. A rectangular spring holder

50

serves as a base for a plurality of springs

52

a

-

52

n

whose purpose is to provide inwardly directed pressure to position the upper and lower bus bars

32

and

34

into electrical contact with and across the contacts

26

and

28

when allowed by the position of a cam

54

.

The enclosure bottom

12

and the enclosure top

14

together form an enclosure to which components align and secure about and within, including, but not limited to, the bifurcated contact assembly

30

, the rectangular spring holder

50

and springs

52

a

-

52

n

, the upper and lower contact guides

46

and

48

, the small switch terminal

18

, the large switch terminal

20

, the solenoid

16

, a solenoid operated cam driver arm

56

, and the cam

54

and associated members. The cam

54

and the associated members including a cam pivot pin

58

, a cam driver

60

, a carrier driver

62

, springs

64

a

and

64

b

, and balls

66

a

and

66

b

are located and/or secured between the enclosure bottom

12

and the enclosure top

14

each of which includes suitable geometrical configurations to accommodate the cam

54

and associated cam related members as well as other elements of the invention.

The enclosure bottom

12

(

FIG. 6

) includes a substantially planar bottom

68

, a vertically aligned end

70

, an open end opposing the end

70

, and a vertically aligned left side

72

and right side

74

. Cutouts

72

a

and

74

a

in the left and right sides

72

and

74

accommodate and support the vertically oriented planar structure

20

e

and the vertically oriented planar structure

18

b

of the small switch terminal

18

and the large switch terminal

20

, respectively, which in part anchor the large switch terminal

20

and the small switch terminal

18

. The bottom

68

includes geometrically configured recessed or other regions on its upper surface including a channeled recess

76

which intersects a circular recess

78

, an elongated recess

80

located in the channeled recess

76

, a circular recess

82

located central to the circular recess

78

, an upwardly extending solenoid core stop

84

, and a rectangular recess

86

for accommodation of the lower contact guide

48

. Also included are rectangular recesses

88

and

90

for the accommodation of the combined lower ends of contact

28

/contact mounting pad

20

f

and the combined lower ends of contact

26

/contact mounting pad

18

c

, respectively, which can in part anchor the large switch terminal

20

and the small switch terminal

18

. Geometrically configured capturing slots

92

and

94

are located on the underside of the bottom

68

for positive mating with the tabs

96

and

98

of the framework

100

of the solenoid

16

.

The enclosure top

14

(shown inverted in

FIG. 7

) also includes geometrically configured capturing slots

102

and

104

located on the top surface for positive mating with tabs

95

and

97

of the framework

100

of the solenoid

16

. Also included are recesses

106

and

108

for accommodation of portions of the vertically oriented planar structures

20

e

and

18

b

of the large switch terminal

20

and the small switch terminal

18

. The enclosure top

14

includes geometrically configured recessed or other regions on its lower surface, some of which are similar to those found on the enclosure bottom

12

, including a rectangular recess

110

for accommodation of the upper contact guide

46

, rectangular recesses

112

and

114

for the accommodation of the combined upper ends of contact

28

/contact mounting pad

20

f

and the combined lower ends of contact

26

/contact mounting pad

18

c

, respectively, which can in part anchor the large switch terminal

20

and the small switch terminal

18

. In addition, a circular recess

116

in opposition to circular recess

82

of the enclosure bottom

12

is located on the undersurface of the enclosure top

14

. Together, circular recesses

116

and

82

serve as upper and lower mounts for the cam pivot pin

58

. A series of detent grooves

118

a

-

118

n

having ramped depth are located concentric to the circular recess

116

.

The cam

54

, and other associated components, are located along and about the vertically oriented cam pivot pin

58

. The cam driver

60

(shown inverted in

FIG. 8

) is substantially disk-shaped and includes a centrally located hole

120

extending therethrough, a plurality of ratchet teeth

122

a

-

122

n

on the upper side, a recessed portion

124

on the lower side, and an engagement hole

126

extending vertically through the cam driver

60

in the area of the recessed portion

124

. The cam driver

60

aligns over and about and is allowed to be actuated about the cam pivot pin

58

. The cam driver

60

freely aligns in the circular recess

78

in the bottom

68

of the enclosure bottom

12

. Aligned in the channeled recess

76

of the enclosure bottom

12

is the cam driver arm

56

which includes a cam driver pin

57

extending vertically through and extending both above and below the cam driver arm

56

. The lower end of the cam driver pin

57

is freely accommodated by the elongated recess

80

in the bottom

68

of the enclosure bottom

12

and the upper end of the cam driver pin

57

rotatingly engages the engagement hole

126

. Hole

126

is slightly larger than the diameter of the cam driver pin

57

to allow for non-bonding engagement of the cam driver pin

57

with the hole

126

, as hole

126

moves along an arcuate path during rotation about the cam pivot pin

58

. The solenoid

16

, which includes a solenoid core

128

, a pole face

130

, a spacer

132

, a bobbin

134

, a guide pin

136

, a core stud assembly

138

, a spring

139

, and the framework

100

, actuates the cam driver arm

56

to subsequently rotate the cam driver

60

in a counterclockwise fashion. Also aligned freely over and about the cam pivot pin

58

as well as aligned in intimate contact with the cam driver arm

56

is the carrier driver

62

.

The cam driver

62

(also shown in

FIG. 9

) includes vertically aligned cylindrical spring mounts

140

and

142

extending from its top surface for mounting of the lower ends of the springs

64

a

and

64

b

and also includes a plurality of ratchet teeth

144

a

-

144

n

located along and extending downwardly from the bottom surface. Ratchet teeth

144

a

-

144

n

accommodatingly correspond to and intimately contact and positively engage (in one direction) the ratchet teeth

122

a

-

122

n

on the upper surface of the cam driver

60

. Positive engagement of ratchet teeth

122

a

-

122

n

and ratchet teeth

144

a

-

144

n

occurs in a counterclockwise manner when the cam driver arm

56

is actuated inwardly and to the right by the solenoid

16

. Subsequent to this action and when power is interrupted to the solenoid

16

, the recoiling action of the solenoid returns the cam driver arm

56

and thus the cam driver

60

, by virtue of the slipping of the ratchet teeth

122

a

-

122

n

with ratchet teeth

144

a

-

144

n

, in the reverse direction, to the rest or non-actuated position after positioning of the carrier driver

62

. Such cycling of the solenoid

16

provides for 45° counterclockwise rotational repositioning of the carrier driver

62

and of the attached cam

54

. Such repositioning provides for repositioning of the bifurcated contact assembly

30

to either make or break electrical contact across the contacts

26

and

28

.

The cam

54

, shown inverted in

FIG. 10

, includes a plurality of vertically aligned cam lobes

146

a

-

146

n

which align in parallel and concentric fashion to a centrally located annular centering extension

148

on the underside of the cam

54

and which also align in parallel and concentric fashion to a co-located pivot hole

150

extending through the body of the cam

54

and extending through the annular centering extension

148

. Structure of the cam

54

and the relationship to the underlying structures is found in the description of FIG.

10

. Also visible are the upper regions of spring bores

152

and

154

to which balls

66

a

and

66

b

align, respectively. The balls

66

a

and

66

b

interface between the cam

54

and the detent grooves

118

a

-

118

n

of the enclosure top

14

(

FIG. 7

) to provide detented positional fixation for proper alignment of the cam

54

and to ensure that the cam

54

and the carrier driver

62

are not allowed to rotatingly regress and that they are held in their advanced position as the cam driver

60

returns to the unactuated position upon release of power application to the solenoid

16

.

FIG. 3

illustrates an isometric view of the small switch terminal

18

, where all numerals mentioned previously correspond to those elements previously described. Illustrated in particular is dual and continuous contact

26

having juxtaposed wide V-shaped contact surfaces including surfaces

26

a

and

26

b

which are angled and which mutually intersect and surfaces

26

c

and

26

d

which are angled and which mutually intersect. The surfaces

26

a

and

26

b

provide for multi-point contact with the arc-shaped contact

38

of the upper bus bar

32

and the surfaces

26

c

and

26

d

provide for multi-point contact with the arc-shaped contact

38

of the lower bus bar

34

.

FIG. 4

illustrates an isometric view of the large switch terminal

20

where all numerals mentioned previously correspond to those elements previously described. Illustrated in particular is dual and continuous contact

28

having juxtaposed wide V-shaped contact surfaces including surfaces

28

a

and

28

b

which are angled and which mutually intersect and surfaces

28

c

and

28

d

which are angled and which mutually intersect. The surfaces

28

a

and

28

b

provide for multi-point contact with the arc-shaped contact

36

of the upper bus bar

32

and the surfaces

28

c

and

28

d

provide for multi-point contact with the arc-shaped contact

36

of the lower bus bar

34

.

FIG. 5

illustrates an isometric view of upper bus bar

32

, being identical to lower bus bar

34

, where all numerals mentioned previously correspond to those elements previously described. A guide bar

42

is located transverse to the planar surface

44

at the top region of the bus bar

32

. The guide bar

42

aligns in a channel

156

on one side of the upper contact guide

46

, accommodatingly located in the rectangular recess

110

in the enclosure top

14

, to facilitate to and fro movement of the upper bus bar

32

. A similar arrangement exists between the lower bus bar

34

, which is inverted, and the similarly constructed and inverted lower contact guide

48

accommodatingly located in the rectangular recess

86

in the enclosure bottom

12

, to facilitate to and fro movement of the lower bus bar

34

. It is noted that surface

158

, which is located on the bottom of the upper bus bar

32

, is smooth and comes into intimate and sliding contact with the corresponding smooth surface

158

of the inverted lower bus bar

34

, thus allowing for and promoting independent sliding movement of the upper and lower bus bars

32

and

34

, respectively.

FIG. 6

illustrates an isometric view of the enclosure bottom

12

, where all numerals correspond to those elements previously described.

FIG. 7

illustrates an inverted isometric view of the enclosure top

14

, where all numerals correspond to those elements previously described. A series of detent grooves

118

a

-

118

n

having ramped depth are located concentric to the circular recess

116

. The balls

66

a

and

66

b

which align to the upper region of spring bores

152

and

154

on the upper side of the cam

54

align in the deepest region of opposing detent grooves

118

a

-

118

n

to provide for detented orientation of the cam

54

. Ramping of the detent grooves

118

a

-

118

n

provides for easy and reduced force exit of the balls

66

a

and

66

b

during repositioning of the cam

54

by the solenoid

16

.

FIG. 8

illustrates an inverted isometric view of the cam driver

60

, where all numerals correspond to those elements previously described. Shown in particular is the recessed portion

124

and the engagement hole

126

. The recessed portion

124

provides for accommodation of the cam driver arm

56

.

FIG. 9

illustrates an isometric view of the carrier driver

62

, where all numerals mentioned previously correspond to those elements previously described. The carrier driver

62

includes vertically aligned cylindrical spring mounts

140

and

142

extending from its top surface for mounting of the lower ends of the springs

64

a

and

64

b

and also includes a plurality of ratchet teeth

144

a

-

144

n

located along and extending downwardly from the bottom surface. Also included is a centrally located locator hole

160

which is incorporated for accommodation of the annular centering extension

148

extending downwardly from the cam

54

. Such accommodation provides for vertical alignment of the cam

54

with and over and about the carrier driver

62

.

FIG. 10

illustrates an inverted isometric view of the cam

54

, where all numerals mentioned previously correspond to those elements previously described. Shown in particular is the annular centering extension

148

and an annular space

162

located about and between the annular centering extension

148

and the cam lobes

146

a

-

146

n

. The annular space

162

is also bounded by a planar and circular annular surface

164

. The annular space

162

accommodates the body of the carrier driver

62

. Opposing bores

166

and

168

extend vertically through the body of the cam

54

from the circular annular surface

164

to concentrically meet and align with the spring bores

152

and

154

, respectively. Opposing bores

166

and

168

accommodate spring mounts

140

and

142

of the carrier driver

62

of FIG.

9

. Spring mounts

140

and

142

connectingly interface with the bores

166

and

168

so that rotational motion of the carrier driver

62

, as driven by the cam driver

60

, provides for corresponding rotational movement of the cam

54

. The lower ends of the springs

64

a

and

64

b

align in the respective spring mounts

140

and

142

and the springs extend through the spring bores

152

and

154

where the opposing upper spring ends forcefully align with the balls

66

a

and

66

b

(

FIG. 2

) to force the balls

66

a

and

66

b

into the detent grooves

118

a

-

118

n

(FIG.

7

).

FIGS. 11-14

, each illustrates a partial side view in perspective of the bi-stable battery switch

10

, where all numerals correspond to those elements previously described. The enclosure bottom

12

, the large switch terminal

20

and other members have been removed for the purpose of clarity and brevity. Addition of member elements, especially those elements involved with rotation of the cam

54

, are progressively added as shown in the sequenced views of

FIGS. 11-14

. Shown especially in

FIG. 11

is the cam driver arm

56

attached to the solenoid core

128

and the position of the cam driver arm

56

with relationship to the cam pivot pin

58

.

FIG. 12

illustrates the elements of

FIG. 11

with the addition of the cam driver

60

over and about the cam pivot pin

58

. The cam driver arm

56

aligns in the recessed portion

124

of the cam driver

60

and the cam driver pin

57

aligns in the engagement hole

126

. Pulsed actuation of the solenoid

16

provides for stepped counterclockwise rotary motion of the cam driver

60

about the cam pivot pin

58

, as previously described.

FIG. 13

illustrates the elements of

FIG. 12

with the addition of the carrier driver

62

and the springs

64

a

and

64

b

extending vertically from the spring mounts

140

and

142

, respectively. Particularly shown is the engagement of the cam driver

60

with the carrier driver

62

where ratcheting clutch engagement occurs with actuation of the solenoid

16

, as previously described.

FIG. 14

illustrates the elements of

FIG. 13

with the addition of the cam

54

over and about the cam pivot pin

58

. Cam

54

is shown in the position calling for a continuous circuit through the bi-stable battery switch

10

, or in other words, none of the cam lobes

146

a

-

146

n

is in direct contact with the cam surfaces

40

on the upper and lower bus bars

32

and

34

, respectively; and the springs

52

a

-

52

n

residing in the rectangular spring holder

50

urge the upper and lower bus bars

32

and

34

into intimate physical and electrical contact with the contact

28

as well as the contact

26

(not illustrated).

MODE OF OPERATION

FIGS. 15 and 16

best illustrates the mode of operation of the bi-stable battery switch

10

, the present invention, where all numerals correspond to those elements previously described.

FIGS. 15 and 16

illustrate a cross sectional top view through the large switch terminal

20

U-shaped structure

20

d

of the bi-stable battery switch

10

where the enclosure top

14

has been removed and where a portion of the horizontally oriented structure

20

c

of the large switch terminal

20

is shown in dashed lines.

FIG. 15

illustrates the bi-stable battery switch

10

in the conducting mode where the cam lobes

146

a

-

146

n

of the cam

54

have been rotationally positioned by pulsing of the solenoid

16

and are not directly influencing or in contact with the cam surfaces

40

of the stacked upper and lower bus bars

32

and

34

comprising the bifurcated contact assembly

30

. The plurality of springs

52

a

-

52

n

in the rectangular spring holder

50

are in direct contact with the rear surfaces of the stacked upper and lower bus bars

32

and

34

to directly urge and force contact of the stacked upper and lower bus bars

32

and

34

across the contacts

26

and

28

, thus completing the through electrical contact across and between the small switch terminal

18

and the large switch terminal

20

to make battery power available for a vehicle or other object.

FIG. 16

illustrates the bi-stable battery switch

10

in the non-conducting mode where the cam

54

has been rotated by pulsing of the solenoid

16

to overcome the force of the plurality of springs

52

a

-

52

n

to rotationally position one of the cam lobes

146

a

-

146

n

of the cam

54

into direct contact with both of the cam surfaces

40

of the stacked upper and lower bus bars

32

and

34

, thereby repositioning the stacked upper and lower bus bars

32

and

34

to interrupt contact of the stacked upper and lower bus bars

32

and

34

across the contacts

26

and

28

, thus terminating the electrical contact across and between the small switch terminal

18

and the large switch terminal

20

. Each time the solenoid

16

is pulsed by actuation of a hand held remote signaling device, electrical contact across the bi-stable battery switch

10

is made or broken to supply or interrupt supply voltage from a host battery. Although both positionable bus bars

32

and

34

are springingly and simultaneously urged toward and into intimate dual contact with the stationary and wide contacts

26

and

28

located on the small and large switch terminals

18

and

20

, one positionable bus bar precedes, in a very short time span, the adjoining positionable bus bar and picks up the arcing load in contacting the stationary and wide contacts

26

and

28

of the small and large switch terminals

18

and

20

only to be closely followed by the remaining positionable bus bar which in contacting the stationary and wide contacts

26

and

28

of the small and large switch terminals

18

and

20

picks up the current load. Conversely, when contact is broken by rotational repositioning of the cam

54

, one of the positionable bus bars

32

or

34

leads, in a very short time span, the adjoining positionable bus bar and releases the load current in breaking the contact across the stationary and wide contacts

26

and

28

of the small and large switch terminals

18

and

20

only to be closely followed by the remaining repositioning bus bar which releases the arcing load contact across the stationary and wide contacts

26

and

28

of the small and large switch terminals

18

and

20

.

FIG. 17

illustrates the incorporation of the present invention, the bi-stable battery switch

10

, into the top portion

180

of a storage battery such as used in an automobile or in a variety of other objects. A negative terminal

182

would attach to the negative plates (not illustrated) of the storage battery, and, for purposes of example and illustration, another terminal

184

, a switched positive terminal, would connect to the large switch terminal

20

at the horizontally oriented planar structure

20

a

utilizing attachment hole

24

. The small switch terminal

18

would connect to the positive plates of the storage battery utilizing the horizontally oriented planar structure

18

a

at attachment hole

22

. In the alternative, another terminal

186

could attach to the attachment hole

22

if it is desired to have limited battery power available for other items such as burglar alarms or other accessories not related to disabling the delivery of battery power to a vehicle.

BI-STABLE BATTERY SWITCH

PARTS LIST

10

bi-stable battery switch

12

enclosure bottom

14

enclosure top

15

clip

16

solenoid

18

small switch terminal

18a

horizontally oriented planar structure

18b

vertically oriented planar structure

18c

contact mounting pad

20

large switch terminal

20a

horizontally oriented planar structure

20b

vertically oriented planar structure

20c

horizontally oriented planar structure

20d

U-shaped structure

20e

vertically oriented planar structure

20f

contact mounting pad

22

hole

24

attachment hole

26

contact

26a-d

surfaces

28

contact

28a-d

surfaces

30

bifurcated contact assembly

32

upper bus bar

34

lower bus bar

36

arc-shaped contact

38

arc-shaped contact

40

cam surface

42

guide bar

44

planar surface

46

upper contact guide

48

lower contact guide

50

rectangular spring holder

52a-n

springs

54

cam

56

cam driver arm

57

cam driver pin

58

cam pivot pin

60

cam driver

62

carrier driver

64a

spring

64b

spring

66a

ball

66b

ball

68

bottom

70

end

72

side, left

72a

cutout

74

side, right

74a

cutout

76

channeled recess

78

circular recess

80

elongated recess

82

circular recess

84

solenoid core stop

86

rectangular recess

88

rectangular recess

90

rectangular recess

92

capturing slot

94

capturing slot

95

tab

96

tab

97

tab

98

tab

100

framework

102

capturing slot

104

capturing slot

106

recess

108

recess

110

rectangular recess

112

rectangular recess

114

rectangular recess

116

circular recess

118a-n

detent grooves

120

hole

122a-n

ratchet teeth

124

recessed portion

126

engagement hole

128

solenoid core

130

pole face

132

spacer

134

bobbin

136

guide pin

138

core stud assembly

139

spring

140

spring mount

142

spring mount

144a-n

ratchet teeth

146a-n

cam lobes

148

annular centering extension

150

pivot hole

152

spring bore

154

spring bore

156

channel

158

smooth surface

160

locator hole

162

annular space

164

circular annular surface

166

bore

168

bore

180

battery top

182

negative terminal

184

positive terminal

186

terminal

Various modifications can be made to the present invention without departing from the apparent scope hereof.

Bi-stable battery switch

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

US Referenced Citations (1)