Automatic door assembly and door operator therefor

BACKGROUND AND SUMMARY OF THE INVENTION

Swing door operators are well-known in the automatic door assembly art for controlling the pivoting movements of pivoting or swing door panels between open and closed positions thereof. In most automatic door assemblies, the door panel is moved under power by the door operator in a normal motor driven door opening direction in response to an input device thereof detecting the presence of a person or object adjacent to the door assembly. One problem with conventional swing door operators is that they are difficult and oftentimes costly to service. For example, in order to service the motor of the operator, a technician must remove the operator from the door assembly and disassemble the operator housing to access the motor. This is a time consuming operation in view of the fact that the amount time spent servicing the motor itself is often quite short in comparison to the amount of time spent removing the operator and disassembling its housing. For example, in the case of a burnt-out motor, the technician can remove the old motor and replace the same with a new one very quickly, but will end up spending substantially more time removing the operator, disassembling its housing, re-assembling its housing, and remounting the operator. Consequently, there exists a need in the art for a door operator that has improved servicability to provide for easier and quicker servicing.

It is therefore an object of the present invention to meet the above-described need. To achieve this object, one aspect of the present invention provides a door operator comprising a rotatable operator output member constructed and arranged to be operatively connected with the door panel such that rotation of the output member moves the door panel between the open and closed positions thereof. A housing of the operator has an opening providing access to the interior of the housing. The operator further comprises a motor disposed within the interior of the housing in an operating position wherein the motor is coupled to the operator output member such that operation of the motor rotates the output ember so as to move the door panel between the open and closed positions thereof. The motor and the opening of the housing are configured with respect to one another to enable the motor to be moved out of the operating position thereof outwardly through the opening for servicing of the motor without disassembling the housing. The motor and the opening of the housing are also configured with respect to one another to enable the motor to be moved inwardly through the opening to reposition the motor in the operating position thereof within the housing interior.

In the preferred embodiment of this aspect of the invention a releasable fastener is accessible through the opening of the housing from an exterior thereof. The fastener is constructed and arranged to be selectively manipulated through the opening in a motor releasing manner to release the motor to allow for removal of the motor from the operating position thereof and in a motor securing manner to releasably secure the motor in the operating position thereof within the interior of the housing.

A related aspect of the present invention provides a method for servicing a door operator comprising (a) a rotatable operator output member, the operator output member being constructed and arranged to be operatively connected with the door panel such that rotation of the output member moves the door panel between the open and closed positions thereof; (b) a housing having an opening providing access to the interior of the housing; and (c) an installed motor disposed within the interior of the housing in an operating position wherein the motor is coupled to the operator output member such that operation of the motor rotates the output member so as to move the door panel between the open and closed positions thereof, the installed motor and the opening of the housing being configured with respect to one another to enable the installed motor to be moved out of the operating position thereof outwardly through the opening for servicing of the motor without disassembling the housing. The method according to this related aspect of the invention comprises releasing the installed motor to allow for removal of the installed motor from the operating position thereof; moving the released motor out of the operating position thereof outwardly through the opening of the housing without disassembling the housing; providing a reinstallation motor, the reinstallation motor and the opening of the housing being configured with respect to one another to enable the reinstallation motor to be moved inwardly through the opening to position the reinstallation motor in the operating position thereof within the housing interior; moving the reinstallation motor inwardly through the opening to install the reinstallation motor in the operating position within the housing interior such that the reinstallation motor is coupled to the operator output member such that operation of the reinstallation motor rotates the output member so as to move the door panel between the open and closed positions thereof; and securing the installed reinstallation motor in the operating position within the interior of the housing.

Providing the reinstallation motor in accordance with this aspect of the invention may be accomplished either by servicing the released motor or by providing a replacement motor. Servicing the released motor may comprise inspecting the released motor, repairing the released motor, or both. During inspecting, it may be determined that the released motor is damaged but should be repaired (i.e. because it is beyond repair or because the cost of repair is not justified in view of the cost of providing a replacement motor) and then providing the reinstallation may be performed by the providing a replacement motor.

U.S. Pat. No. 5,386,885 discloses a door operator comprising a torsion spring that becomes wound during door opening to store energy and thereafter releases that stored energy by unwinding to rotate a striker disk to effect pivotal movement of the door panel in the closing direction thereof. The rear volute of the spring is fixed to a support disk that can be rotated to tension or relax the torsion spring via winding or unwinding the same to control an amount of spring force applied. However, the support disk during rotation thereof remains in the same axial position with respect to the spring. As a result, this arrangement is not suitable for adjusting spring force in an operator in which the return spring is used in compression spring instead of torsion to effect spring driven door panel movement because it does not stress the spring by compression or extension, which is the way in which a compression spring functions to effect door panel movement. Thus, there exists a need for a simple and effective arrangement for adjusting spring force in a door operator in which spring force is provided by a compression spring instead of a torsion spring.

It is therefore another object of the present invention to meet the above-described need. To achieve this object, another aspect of the invention provides a door operator comprising a rotatable operator output member rotatable about an operator output axis. The operator output member isg constructed and arranged to be operatively connected with the door panel such that rotation of the output member moves the door panel between the open and closed positions thereof. A motor is coupled to the operator output member such that operation of the motor rotates the output member so as to move the door panel between the open and closed positions thereof. A door moving compression spring structure is positioned in a spring force applying relationship with respect to the operator output member such that operating the motor to rotate the output member in the first rotational direction thereof to move the door panel in a first door moving direction stresses the spring structure. The spring structure is constructed and arranged to thereafter apply a spring force to the operator output member that tends to rotate the operator output member in a second rotational direction opposite the first rotational direction to move the door panel operatively connected thereto in a second door moving direction opposite the first door moving direction. The operator also comprises a selectively movable spring force adjusting member operatively associated with the compression spring structure, the spring force adjusting member being selectively movable in a generally longitudinal direction of the spring structure through a range of adjusting positions to control an extent to which the spring is stressed during movement of the door panel in the first door moving direction thereof, thereby enabling the amount of spring force that the spring structure applies to the operator output member during rotation in the second rotational direction to be selectively adjusted.

A related aspect of the invention provides a method for adjusting spring force in a door operator comprising (a) a rotatable operator output member rotatable about an operator output axis, the operator output member being constructed and arranged to be operatively connected with the door panel such that rotation of the output member moves the door panel between the open and closed positions thereof; (b) a motor coupled to the operator output member such that operation of the motor rotates the output member so as to move the door panel between the open and closed positions thereof; (c) a door moving compression spring structure positioned in a spring force applying relationship with respect to the operator output member operating the motor to rotate the output member in the first rotational direction thereof to move the door panel in a first door moving direction stresses the spring, the spring structure being constructed and arranged to thereafter apply a spring force to the operator output member that tends to rotate the operator output member in a second rotational direction opposite the first rotational direction to move the door panel operatively connected thereto in a second door moving direction opposite the first door moving direction; and (d) a selectively movable spring force adjusting member operatively associated with the compression spring structure, the spring force adjusting member being selectively movable in a generally longitudinal direction of the spring structure through a range of adjusting positions to control an extent to which the spring is stressed during movement of the door panel in the first door moving direction thereof. The method of this aspect of the present invention comprises moving the spring force adjusting member in the generally longitudinal direction of the compression spring structure to a selected position within the range of adjusting positions such that the spring structure is stressed to an extent determined by the selected position of the adjusting member to adjust the amount of spring force that the spring structure applies to the operator output member during rotation in the second rotational direction.

It is known in the door operator art to provide one or more stop members to limit the range of rotation for the operator output member, thereby limiting the range of pivotal movement for the door panel to which it is connected. U.S. Pat. No. 4,727,679 discloses a pair of such stop member at 90 and 92 in the drawings thereof. However, it is often desirable to increase or decrease the range of pivotal movement as conditions around the door assembly change. For example, a store owner may desire to place a merchandise display next to the door assembly and require that the pivotal range of the panel be decreased to prevent it from hitting the display. The '679 patent does not provide for an easy way to change the range of pivotal movements to accommodate such a situation.

To achieve this object, another aspect of the present invention provides a swing door operator for controlling pivoting movements of a door that pivots about a generally vertical door axis from a closed position through a range of open positions. The operator comprises a rotatable operator output member constructed and arranged to be operatively connected with the door panel such that rotation of the output member pivots the door panel about the door panel axis thereof. A motor is coupled to the operator output member such that operation of the motor rotates the output member so as to move the door panel through the range of open positions thereof. A first stop member is operatively connected to the operator output member such that rotation of the output member rotates the first stop member. A second stop member is mounted adjacent the output member. The second stop member is constructed and arranged such that the first stop member engages the second stop member during rotation of the output member so as to prevent further rotation of the output member, thereby limiting a range of rotational movement of the output member and thus limiting the range of open positions through which the door panel pivots. The first and second stop members are constructed and arranged to be adjustably moved relative to one another through a range of adjusting positions and fixed in a selected one of the range of adjusting positions, thereby setting the range through which rotational movement of the output member will be permitted and thus setting the range of open positions through which the door panel pivots.

Another shortcoming with conventional swing door operators is the difficulty associated with adjusting the contact members that contact the contact switches to indicate certain door positions to the controller. Usually, these contact member are eccentric cams hat rotate along with the output member. However, these contact members are difficult to access when installing the operator. As a result, proper positioning of the contact members with respect to the switches and the door panel's range of movement is difficult to achieve during installation. U.S. Pat. No. 5,221,239. The entirety of which is hereby incorporated into the present application by reference, illustrates a prior art door operator wherein the switch cams are housed within an upper housing located above the main housing. Access to these switch cams requires removal of the upper housing to affect adjustment during door installation.

A further aspect of the present invention provides a swing door operator for use in conjunction with a controller for controlling pivoting movements of a door that pivots about a generally vertical door axis from a closed position through a range of open positions. The swing door operator of this aspect of the invention comprises an outermost housing and a rotatable operator output member extending outwardly from the housing. The output member is constructed and arranged to be operatively connected with the door panel such that rotation of the output member pivots the door panel about the door panel axis thereof. A motor is disposed interiorly of the housing. The motor is coupled to the operator output member such that operation of the motor rotates the output member so as to move the door panel through the range of open positions thereof. The motor is communicable with the controller to enable the controller to control operation of the motor. A contact switch is mounted exteriorly of the housing and is communicable with the controller such that contacting the switch transmits a contact signal to the controller. A contact member is mounted exteriorly of the housing adjacent the contact switch and provides a contact switch contacting surface. The contact member is operatively connected to the output member such that rotation of the output member to pivot the door panel through its range of open position affects movement of the contact member through a corresponding range of contact member positions. The contact member is constructed and arranged to contact the contacting surface thereof with the contact switch during movement through the range of contact member positions so as to cause the contact switch to transmit the contact signal to the controller, thereby indicating a corresponding position of the door panel in the range of open positions thereof to the controller for use in controlling operation of the motor. The contact member is adjustable relative to the output member from the exterior of the housing to enable the position within the range of contact member positions at which the contact surface of the contact member contacts the contact switch to be selected with respect to the range of open positions of the door panel.

Other objects, features, and advantages of the present invention will become apparent from the following detailed description, the accompanying drawings, and the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1

is a perspective view of a swing door operator constructed in accordance with the principles of the present invention, the perspective being taken from above the operator;

FIG. 2

is a perspective view of the operator of

FIG. 1

, the perspective being taken from below the operator;

FIG. 3

is perspective view similar to

FIG. 1

, but with the casing of the operator being shown in phantom to illustrate the internal components of the operator;

FIG. 4

is an exploded perspective view of the operator of

FIG. 1

with the upper and lower halves of the motor/reduction gear transmission housing portion separated and the components therein disassembled, the perspective being taken from above the operator;

FIG. 5

is an exploded perspective view of the components that are associated with the underside of the output drive assembly housing portion, including components of the output drive assembly, the adjustable stop member, and the switch element modules, the perspective being taken from below the output drive assembly housing portion;

FIG. 6

is an exploded perspective view of the components that are associated with the interior of the output drive assembly housing portion, including components of the output drive assembly, and the camming structure, the perspective view being taken from above the output drive assembly housing portion with the upper cover plate removed for better illustration;

FIG. 7

is a cross-sectional view taken longitudinally through the operator along the axis of the motor;

FIG. 8

is a perspective view of a D.C. motor utilized in the operator of the present invention, the perspective being taken from the rear of the motor;

FIG. 9

is a perspective view of the D.C. motor of

FIG. 8

, the perspective being taken from the front of the motor;

FIG. 10

is an exploded view of a reduction transmission utilized in the operator of the present invention clearly illustrating the compact planetary gear arrangement assembled therein;

FIG. 11

is a cross-sectional view of the reduction transmission of

FIG. 10

;

FIG. 12

a

is a perspective view of a camming structure and an drive member of the output drive assembly utilized in the operator of the present invention, the camming structure and the drive member being depicted as they would be with the door in the closed position;

FIG. 12

b

is a perspective view similar to

FIG. 12

a

, with the camming structure and the drive member being depicted as they would be with the door opened degrees from its closed position;

FIG. 12

c

is an elevated profile view showing the notch in the underside of the cam structure and the force receiving member on the driving member;

FIG. 13

is a graph illustrating the amount of force (in pounds) applied in the closing direction of the door versus the number of degrees from which the door is pivoted from its closed position with the force being illustrated along the vertical axis and the number of degrees being illustrated along the horizontal axis;

FIG. 14

is a perspective view of a swing door assembly in which the operator of

FIG. 1

may be used;

FIG.

15

(

a

) is an elevated end view of a door operator of the invention with an alternative stop arrangement;

FIG.

15

(

b

) is an elevated profile view of the operator of FIG.

15

(

a

); and

FIG.

15

(

c

) is a bottom view of the operator of FIG.

15

(

a

).

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT OF THE INVENTION

FIG. 1

shows a perspective view of a swing door operator, generally indicated at

10

, constructed in accordance with the principles of the present invention, the perspective being taken from above the operator.

FIG. 2

shows a perspective view taken from below the operator

10

. The operator

10

has a stamped, metal outer casing, or housing generally indicated at

12

, comprising a motor/reduction transmission housing portion, generally indicated at

14

, and an output drive assembly housing portion, generally indicated at

16

. The motor/reduction transmission housing portion

14

has upper and lower housing halves

18

,

20

, respectively, that are each secured together to a rearward end portion of the output drive assembly housing portion

16

by a plurality of threaded fasteners

22

, such as conventional bolts or screws. The construction of the upper and lower housing halves

18

,

20

and the manner in which they are secured to the output drive assembly housing portion

16

can be best appreciated from FIG.

4

. The output drive assembly housing portion

16

comprises a lower housing shell

24

with an upwardly facing rectangular opening and a rectangular upper plate

26

that closes the opening of the lower shell

24

. The shell

24

and plate

26

are also secured together by a plurality of fasteners

22

. The construction of the upper plate

26

and the lower housing shell

24

can be best appreciated from

FIGS. 5 and 6

. A set of threaded bores

28

are provided on the casing

12

so that the operator

10

can be mounted in its operating position above a swinging door (not shown). The operator

10

may mounted directly above the door in its door jamb or in a laterally extending header provided on the frame

504

of the automatic door assembly

500

(see FIG.

14

), but it may be offset and extend laterally away from the door, depending on space restrictions.

An operator output member

30

extends downwardly from the lower housing shell

24

of housing portion

16

and is rotatable about an operator output member axis. The output member

30

has an elongated pinion gear portion

31

that is constructed and arranged to be operatively connected directly to a swinging door panel

506

(shown in

FIG. 14

) that pivots back and forth in opening and closing directions about a generally vertically extending door panel axis. The connection between the door panel

506

and the output member

30

may be indirect via an intervening connector, such as an intervening gear or shaft or a linking arm; or it may be direct. To directly connect the operator to the swinging door panel

506

, the output member

30

is inserted into a bore (not shown) having internal gear teeth formed coaxially with the door axis on the upper portion of the door panel

506

. The teeth of the output member

30

engage the teeth formed inside the bore in a fixed intermeshed relationship so that rotation of the output member

30

pivots the door panel

506

about its axis and, conversely, pivoting the door panel

506

about it axis will rotate the output member

30

. The end of the output member

30

may be configured differently to cooperate with door panels

506

having different types of bores for receiving the output member

30

. For example, some doors may have an oval, non-toothed bore and thus it would be necessary to provide an output member with a corresponding oval shape.

A rotating stop member

32

(referred to as an operator stop member) having an internally toothed bore

34

(the bore is best seen in

FIG. 5

) is mounted over the outer end of the output member

30

with the internal teeth of bore

34

fixedly intermeshed with the teeth on the exterior of a pinion gear or splined portion of the output member

30

. The stop member

30

rotates along with the output member

30

and has an eccentric configuration that extends radially with respect to the axis of the output member

30

. As best seen in

FIG. 4

, the stop ember

32

has a rounded radially outer surface

36

and a pair of generally radially extending side surfaces

38

that taper inwardly towards one another away from the outer surface

36

. The configuration of the stop member

32

, although eccentric, is generally symmetrical with respect to a centerline taken radially to the output member axis between the side surfaces

38

.

An adjustable stop member

40

is mounted on the underside of the lower housing half

20

of the output drive assembly housing portion

16

by a pair of fasteners

42

. The housing portion

16

has a rectangular recessed space

44

in which the stop member

40

is mounted. As best seen in

FIG. 5

, a fixed toothed structure in the form of mounting plate

46

is mounted within the space

44

by a set of fasteners

47

in the form of screws. The mounting plate

46

has a toothed surface

48

with teeth arranged in a generally radial direction wit respect to the operator output axis and a pair of threaded bores for receiving the fasteners

42

. The adjustable stop member

40

also has a toothed surface (not shown) with teeth arranged in a generally radial direction with respect to the operator output axis configured to intermesh or mate with the teeth on mounting plate

46

and a longitudinal slot

50

through which the fasteners

42

can be inserted. The adjustable stop member

40

is fixedly mounted by positioning it on the mounting plate

46

with the teeth of each intermeshed, then inserting the fasteners

42

through the slot

50

and into the threaded bores of the plate

46

, and finally tightening the fasteners

42

to lock the stop member

40

to the plate

46

with the intermeshed teeth preventing relative movement therebetween. The stop member

40

is constructed and arranged to be moved through a range of adjusting positions in a direction that extends generally radially with respect to the output member axis by loosening the fasteners

42

sufficiently to allow the teeth to be disengaged from one another, moving the stop member

40

towards or away from the rotating stop member

32

, and then re-tightening the fasteners

42

to lock the stop member

40

in its new position.

During operation of the operator

10

, the rotating or operator stop member

30

rotates along with the output member

30

about the output member axis. This rotation occurs regardless of whether such rotation is motor driven, spring driven, or as a result of the door being manually pivoted about its axis during breakout. As the stop member

30

rotates, one of the side surfaces

38

thereof will abut against the adjustable stop member

40

to prevent farther rotation of the output member

30

and hence further pivoting of the door panel

506

. The amount of rotation permitted is determined or set by the positioning of the adjustable stop member

40

in its range of adjusting positions. The further radially inwardly the stop member

40

is moved with respect to the output member axis (i.e., the closer to the rotating stop member), the sooner the side surfaces

38

of the rotating stop member

30

will contact the stop member

40

during rotation, thus resulting in a more narrow pivot range for the door panel

506

. Conversely, the further radially outwardly the stop member

40

is moved with respect to the output member axis, the later the side surfaces

38

of the rotating stop member

30

will contact the stop member

40

during rotation, thus resulting in a wider pivot range for the door

506

. The symmetrical configuration of the rotating stop member

30

, specifically the symmetry of the side surfaces

38

, is preferred to provide the door panel

506

with the same pivot range regardless of which direction it pivots during opening. The pivot range is easily adjusted by loosening the fasteners

42

on the adjustable stop member and repositioning the adjustable stop member

42

to a desired location.

The rotating stop member

30

does not necessarily have to be symmetrical. For certain applications, it may be desired to have a wide pivot range in one opening direction and a narrower pivot range in the opposing opening direction. For such applications, a non-symmetrical stop member could be designed. To accommodate different pivot range specifications it is within the scope of the present invention to assemble the rotating stop member

32

in a modular fashion. In this modular fashion, a number of different rotating stop members would be provided and the operator

10

could be marked or otherwise coded as being designed for a specific application. Based on this coding, the appropriate stop member

32

is chosen for the desired application and assembled to the output member

30

. For special applications, a custom-made stop member could be manufactured and assembled to the output member

30

.

The output drive assembly

52

can be best seen in

FIGS. 3

,

5

, and

6

. The output drive assembly

52

comprises the output member

30

, a drive member

54

rotatable about the output member axis, the rotating stop member

32

, a drive assembly input member

56

rotatable about an axis that extends perpendicularly (i.e. radially) to the output member axis, and a rotating bevel gear

58

fixedly mounted to the input member

56

for rotation therewith. The drive member

54

has an associated set of gear teeth

60

formed on the lower side thereof and the bevel gear

58

has an associated set of gear teeth. These sets of gear teeth are engaged with one another intermeshed relation to couple the input and output members together. The elongated pinion gear portion

31

of the output member

30

extends downwardly along the output member axis and a connecting pinion gear portion

62

is formed on the opposing end of the output member

30

. The drive member

54

has a central bore formed therethrough with an internal set of gear teeth

64

. The connecting end portion

62

of the output member

30

is inserted into the central bore with the teeth

64

of the bore and the teeth of the connecting portion

62

fixedly intermeshed together. As a result of this connection, the rotation of the drive member

54

rotates the output member

30

and, conversely, rotation of the output member

30

rotates the drive member

54

.

The drive assembly

52

also includes three contact members in the form of switch cams

66

,

68

,

70

that are mounted exteriorly of the outermost housing

12

for rotation along with the output member

30

, a roller bearing

72

, and a series of thrust bearings

74

. The lower housing shell

24

has a cylindrical receiving portion

76

extending from the lower wall thereof. An opening (not shown) is formed through the lower wall of the lower housing shell

24

inside the receiving portion

76

coaxially with the output member axis to define a wall portion

78

that is continuous with the lower wall of the lower housing shell

24

and that extends radially inwardly from the wall of the cylindrical receiving portion

76

. During assembly, the thrust bearings

74

are placed inside the receiving portion

76

, the roller bearing

72

is abutted against the washers

78

, and the output member

30

is then inserted through the bushing

72

, the thrust bearings

74

, and the opening in wall portion

78

with the connecting end portion

62

thereof extending into the interior of the lower housing shell

24

. The interior diameter of the roller bearing

72

is substantially identical to the exterior diameter of a central smooth, non-geared portion

80

of the output member

30

to ensure that the output member does not move radially or “wobble” during rotation. Also, the thrust bearings

74

function to prevent frictional wear on the output member

30

and the wall portion

78

of the lower shell portion

24

. The roller bearing

72

and thrust bearings

74

are optional, but are preferred to reduce wear and increase component longevity.

A generally cylindrical outer collar

82

having a wide diameter portion

84

and a narrow diameter portion

86

fits over the receiving portion

76

with the wide diameter portion

86

being slidingly received over the receiving portion

76

. Switch cam

70

has a generally cylindrical bore that is force fit over the wide diameter portion of the outer collar

82

and switch cams

66

and

68

each have a generally cylindrical bore that is force fit over the narrow diameter portion

86

. The collar

82

is keyed to the stop member

32

so that the switch cams

66

,

68

,

70

rotate together with the output member

30

and the stop member

32

. A plurality of contact switches modules

236

,

238

,

240

, and

242

each including a contact switch are mounted to the underside of the housing

12

adjacent the output member

30

and the switch cams

66

,

68

,

70

. During such rotation of the output member

30

to affect movement of the door panel through the range of open positions thereof, the cams

66

,

68

,

70

are each moved through a corresponding range of contact member positions. Each switch cam

66

,

68

,

70

is constructed and arranged such that a contact surface thereof engages an associated contact switch which each are communicable to the door assembly controller (not shown) to transmit a contact signal to the controller indicating the that switch has been contacted or “tripped.” This indicates to the controller the corresponding position of the door panel so that the controller can control operation of the motor using this information concerning door panel position. The elongated pinion gear portion

31

extends outwardly beyond the switch cams

66

,

68

,

70

and the stop member

30

attached thereto as described above.

The four switch modules

236

,

238

,

240

, and

242

are removably mounted to the lower housing shell

24

adjacent the switch cams

66

,

68

,

70

. Each switch module includes a conventional relay contact switch which is engaged by an associated one of the switch cams during rotation of the output member

30

. The contact switches are connected to the controller by wires which are not shown in the Figures. The lower two switch modules

236

,

238

adjacent the stop member

32

are engaged by switch cam

66

when the output member

30

rotates as a result of the door being opened in the “breakout” direction—i.e., pivot beyond fully closed opposite the direction in which the door usually opens. When the relay switches of the two lower contact switch modules

236

,

238

are tripped by the switch cam

66

, the controller will cut off power to the motor

116

to prevent operation thereof. Most building codes require such a feature to prevent persons from activating the motor while the door is pushed to a breakout position so that the door does not move towards the fully closed position. The contact relay of the third switch

240

adjacent the second lowers switch module

238

is engaged by switch cam

68

during rotation thereof. This switch is triggered by switch cam

68

when the door is approximately 10 degrees from fully closed and signals the controller to increase the resistance of the motor so that the last 10 degrees of closure occurs at a lower rate against the increased motor resistance. The top switch module

242

is an auxiliary switch module and may be used for a wide variety of purposes. The relay contact of module switch

242

is engaged by switch cam

66

during rotation of the output member

30

. One exemplary use for such an auxiliary switch module

242

is to allow the controller to count the number of times the door has been opened or closed. Other various uses will be readily understood by those skilled in the art.

Each of the switch modules

236

,

238

,

240

,

242

has a pair of apertures formed therethrough. The apertures of the modules are aligned and a pair of threaded fasteners

244

removably secure the switch modules

236

,

238

,

240

,

242

to the lower wall of the lower housing shell

24

. The location and the accessibility of the switch modules is particularly advantageous because it allows for easy replacement of worn-out modules. The switches in known operators are difficult to access and typically require taking the entire operator out from above the door to replace worn-out switches. In the arrangement of the present application, the modules

236

,

238

,

240

,

242

are located on the casing

18

exterior and can be changed without removal of the entire operator

10

from its operating portion above the door.

This reduces the maintenance time spent replacing worn-out switches and reduces overall maintenance costs.

Each of the switch cams

66

,

68

,

70

(i.e. the contact members) is adjustable relative to the output member

30

from the exterior of said housing

12

to enable the position within the range of contact member positions at which each contact surface of the cams

66

m

68

,

70

contacts its associated contact switch to be selected with respect to the range of open positions of said door panel. In the illustrated embodiment, each switch cam

66

,

68

,

70

is mounted to the output member

30

for rotation therewith and each contact switch is mounted adjacent

30

output member and its associated switch cam. Other alternative arrangements are contemplated. Each switch cam

66

,

68

,

70

is constructed and arranged such that adjustment of each switch cam

66

,

68

,

70

relative to the output member

30

is affected by rotating the cams

66

,

68

,

70

about the output member

30

. As mentioned above, each of the cams

66

,

68

,

70

are mounted on the collar in a friction fit relation. As a result, the contact members can each be adjusted relative to the output member

30

by rotation thereof relative to the collar

82

and the output member

30

with sufficient torque to overcome the friction fit between the collar

82

and the cam bore.

The drive assembly

52

also comprises another series of thrust bearings

88

which are disposed over the connecting end portion

62

of the output member

30

and engaged with the interior side of wall portion

78

. The generally circular drive member

54

is connected to the connecting end portion

62

as described above. The connecting end portion

62

has a threaded bore

89

formed therein and the drive member

54

has a shoulder surface

90

surrounding the periphery of the central bore with teeth

64

. A headed threaded fastener

92

in the form of a bolt is inserted into the bore

89

with the head of the fastener

92

engaging the shoulder surface

90

to secure the drive member

54

in place. As with thrust bearings

74

, thrust bearings

88

are not necessary, but are preferred to reduce frictional wear between wall portion

78

and the underside of the drive member

54

.

The rearward wall of the lower housing shell portion

24

has a generally cylindrical input receiving portion

94

extending rearwardly therefrom with an opening

96

formed therethrough providing access to the interior of the housing portion

16

. The bevel gear

58

is fixedly mounted on the forward end

95

of the drive assembly input member

56

. Preferably, the interior of the bevel gear

58

and the exterior of the forward end

95

are toothed and fixedly intermeshed to provide for such fixed mounting but other secure connections may be used. The rearward end of the input member

56

defines a transmission connecting portion

98

in the form of a toothed pinion gear. The central portion of the input member

56

is rotatably supported by a pair of bearings

100

,

102

. The input member

56

is assembled inside the opening

96

of the receiving portion

94

so that the bevel gear

58

is positioned inside the interior of the housing portion

16

and the teeth of the bevel gear

58

are engaged with the teeth

60

on the underside of the drive member

54

in an intermeshed relationship. The connecting portion

98

of the input member

56

extends rearwardly and is accessible through the opening

96

. As a result of this arrangement, rotation of the input member

56

and bevel gear

58

about the input member axis, which extends generally perpendicularly from the output member axis, causes the output member

30

to rotate about the output member axis via the intermeshed sets of gear teeth.

The drive member

54

also has a pin

104

mounted thereon and spaced radially from the output member axis. A cam follower

106

is rotatably mounted on the exterior of the pin

104

. Although the cam follower

106

illustrated is rotatable, it is contemplated that the cam follower could be eliminated and the fixed pin

104

could function as the cam follower

106

. The rotatable cam follower

106

is preferred to prevent friction wear during a camming operation which will be discussed in further detail below. The pin

104

and cam follower

106

may be considered to constitute an offset portion. This offset portion is not limited to the pin

104

and follower

106

arrangement and any structure may be used to provide the offset portion. A camming structure

108

(shown fully in

FIGS. 12

a

and

12

b

) has a forward end portion

110

and a pair of generally cylindrical connection rods

112

extending rearwardly from the forward end portion

110

located inside the drive assembly housing portion

16

. The connecting rods

112

extend rearwardly through a pair of generally circular openings formed in the rear wall of the lower housing shell

24

. A pair of sleeves

114

fit over the ends of the connecting rods

112

which extend rearwardly from the lower housing shell

24

. The function of the camming structure

108

will be explained in further detail below. The upper cover plate

14

is fixed to the top of the lower housing shell half

24

to protect the components housed therein from damage and debris.

FIGS. 8 and 9

illustrate a conventional D.C. motor

116

. The D.C. motor has a cylindrical casing

118

and, as seen best in

FIGS. 4 and 7

, is received inside a generally cylindrical motor/transmission sleeve

120

which, in turn, is received inside the motor/transmission housing portion

14

of the casing

12

. The casing

118

has a generally circular front wall

117

and a generally circular rear wall

119

secured thereto by conventional fasteners such as headed screws. Such conventional D.C. motors are well known and hence the details of the motor

116

will not be described in specific detail. It is preferred that the motor

116

be of the type whose rotational output can be reversed by reversing the polarity of the current flowing to the motor

116

. A controller (not shown) is conventionally used to control the operation of the motor and perform such polarity switching. The use of such controllers for door operators is well-known and therefore such a controller will not be detailed herein. A set of wires

121

extend from the rear end of the motor

116

and an adapter

122

is provided on the free end of the wires

120

for connection to the controller.

The motor drive shaft

124

extends through the casing

118

and has a forward end portion

126

thereof extending through the front wall

117

and a rearward end portion

128

thereof extending through the rear wall

119

. The forward end portion

126

is rotatably supported by a bearing

130

which is press-fit or otherwise mounted in an opening formed through the front wall

126

. A motor output member

132

in the form of a spur or pinion gear is fixedly mounted to the front end portion

126

of the motor shaft

124

. Supplying a direct electrical current to the motor

116

drives the motor shaft

124

in a conventional manner to rotate the motor output member

132

about a motor driving axis (also referred to as a motor output axis) which extends coaxially with the shaft

124

and perpendicularly to the operator output member axis. In the illustrated embodiment the drive assembly input member

56

, the transmission

150

(described below), and the motor shaft

124

share a common axis; however, these elements could be rotated about offset axes and additional gearing could be provided through the transmission to provide for proper power delivery. The coaxial arrangement illustrated is preferred due to space considerations and to obviate the need for additional gearing and its associated part and assembly costs.

A generally circular member

134

is fixedly mounted to the rearward end portion of the shaft

124

for rotation therewith. The circular member

134

has portions of magnetized material spaced circumferentially about the outer periphery thereof at evenly spaced increments. A motor metering device

136

is secured to the rear wall

119

of the motor by a pair of threaded fasteners

138

. Wires

140

extend from the metering device

136

and have an adapter

142

on the free end thereof which connects to the controller. The metering device

136

includes a Hall sensor which is responsive to the magnetic material in the circular member

134

. The Hall sensor of the device

136

cooperates with the controller to determine the rotational speed of the motor

116

and the amount the door has traveled about its axis by measuring the number of rotations of the circular member

134

and speed of such rotations. This information is then used by the controller to control functioning of the operator

10

in a manner that is known in the art and thus will not be detailed herein.

The operator

10

of the present invention also includes a reduction gear transmission, generally indicated at

150

. The transmission

150

comprises an generally cylindrical outer housing

152

. The interior of the outer housing

150

is splined with a set of axially extending gear teeth

154

which define a ring or orbit gear. A generally circular front cover

156

closes the front end of housing

152

and is secured to the housing

152

by conventional fasteners such as threaded screws

158

. A generally circular rear cover

160

closes the rear end of the housing

152

and is also secured to the housing

152

by conventional fasteners such as threaded screws

158

. The front cover

156

has a central opening

162

providing access to the transmission interior and the rear cover

158

has a central opening

164

providing access to the transmission interior.

Three planet gear carriers

166

,

168

,

170

are received inside the housing

152

. Each planet carrier

166

,

168

,

170

has three planet gear mounting pins

172

,

174

,

176

, respectively extending rearwardly therefrom. Three sets of three planet gears each, generally indicated at

178

,

180

, and

182

, are rotatably mounted on the planet gear mounting pins

172

,

174

,

176

, respectively. Although the illustrated embodiment illustrates three carriers each carrying three planet gears, the number of carriers, gears and the diameters thereof may be varied to achieve the desired reduction ratio. The ratio may be increased for applications with doors of greater weight, which require more torque to pivot. Conversely, the ratio may be decreased for applications with lighter doors where a great deal of torque is not needed.

Each of the carriers

166

,

168

,

170

also has a carrier output member

184

,

186

,

188

. The carrier output members

186

,

188

of the rear and central carriers

168

,

170

are in the form of integrally formed pinion gears and the output member

184

of the forward carrier

166

is in the form of a splined bore having a series of axially extending teeth. The rear planetary gear set

182

is mounted on pins

176

and the rear carrier

170

is disposed inside the housing

152

adjacent the rear cover

160

with a metal annular washer

190

positioned between the planet gears

182

and the interior face of the rear cover

160

to prevent fictional wear. The planet gears of set

182

are intermeshed with the teeth

154

lining the inside of the housing

152

. When the operator

10

is assembled, the motor output member

132

is inserted in through the opening

164

of the rear cover

160

and the teeth of the motor output member

132

are intermeshed with the teeth of the planet gears of set

182

. As a result of this arrangement, the planet gears of set

182

will rotate about their respective axes when the motor output member

132

is rotatably driven by the motor

116

and will travel circumferentially about the transmission axis in an intermeshed relationship with the teeth

154

of the housing

152

. The circumferential travel of the planet gears of set

182

causes the rear carrier

170

to rotate about the transmission axis at a rate slower than the motor output member

132

.

The gears of central planet gear set

180

is mounted on pins

174

and the central carrier

168

is disposed adjacent the rear carrier

170

with a metal annular washer

192

positioned between the planet gears

180

and the forward face of the rear carrier

170

to prevent frictional wear. The planets gears of set

180

are intermeshed with the teeth of the output member

188

of the rear carrier

170

and the interior teeth

154

of the housing

152

such that rotation of planet gear carrier

170

will cause the planet gears of set

180

to rotate about their respective axes, which in turn causes the planet gears of set

180

to travel circumferentially with respect to the transmission axis in an intermeshed relation with teeth

154

(i.e., the orbit gear). This circumferential travel rotates the central carrier

168

about the transmission axis at a rate slower than the rear planet gear carrier

170

.

The gears of forward planet gear set

178

are rotatably mounted on pins

172

and the forward carrier

166

is disposed adjacent the central carrier

168

with a metal annular washer

194

positioned between the planet gears

178

and the forward face of the central carrier

168

to prevent frictional wear. The planet gears of set

178

are intermeshed with the teeth of the output member

186

of central carrier

168

and the interior teeth

154

of the housing

152

such that rotation of central planet gear carrier

168

rotates the planet gears of set

178

about their respective axes, which in turn causes the planet gears of set

178

to travel circumferentially with respect to the transmission axis in an intermeshed relation with teeth

154

. As before with carriers

168

and

170

, this circumferential travel rotates the forward gear carrier

166

about the transmission axis at a rate slower than the central planet gear carrier

168

.

When the operator

10

is assembled, the connecting end portion

98

on the output drive assembly input shaft

56

is received through the opening

162

in front cover

156

and inserted into the output member

184

of the forward carrier

166

. The teeth on the connecting end portion

98

engage the teeth on the interior of the output member

184

in a fixedly intermeshed relationship such that rotation of the forward carrier

166

rotates the input member

56

, which in turn drives the output drive assembly

52

in the manner described above to rotate the operator output member

30

. Thus, the output member

184

of the forward carrier

166

may be considered to function as the transmission output.

Because each successive planet gear rotates slower than the output member which drives its planet gears, the rotational speed is significantly lower at the transmission output in comparison to the rotational speed of the motor output member

132

. As a result, the torque at the transmission output is increased in comparison to the effective torque of the motor

116

. This allows high speed/low torque motors (which are less expensive and smaller than low speed/high torque motors) to be used to drive doors with weights which they otherwise could not effectively drive.

The use of a planetary gear arrangement in the reduction transmission

150

is considered to be particularly advantageous because it has an more compact design in comparison to conventional rack/pinion transmission which are utilized in conventional door operators. With conventional door operators, to increase the reduction ratio of a rack/pinion transmission the overall length of the rack must be increased. This results in an increased overall operator length, which may be unsuitable for particular applications due to space considerations and building code requirements. With planetary gear-type transmission, the reduction ratio of the transmission can be greatly increased without significantly increasing the length of the transmission because a greater number of gear teeth can be provided in less space than in a rack/pinion arrangement. For example, to increase the reduction ratio in the illustrated invention, another carrier and another set of planet gears could be assembled inside the housing and the only axial length difference realized would be the axial length of the additional set of gears and their associated carrier. This provides superior savings in overall operator space over conventional arrangements. Further, the transmission

150

of the present invention is also advantageous because no bearings are needed in the gear train, thus obviating the costs and assembly efforts associated with purchasing and mounting such bearings.

Another significant advantage of the transmission

150

illustrated and described herein is that a variety of such transmissions having varying reduction ratios can be assembled the operators in a modular fashion. Specifically, it is contemplated that a bar code or some marking is placed on the operator during assembly. This coding or marking would indicate the appropriate reduction ratio or the part number for the appropriate transmission. The reduction ratio would be selected based on the application for which the operator is to be used. High load operations generally require more torque, and hence and a higher reduction ratio, and low load operations generally require less torque a lower reduction ratio. Also, in low energy applications, building codes require that doors move below a certain speed or carry below a certain amount of energy. For such low energy applications, the low torque would also be desired to ensure that the door moves slowly, and hence a low reduction ratio transmission would be an appropriate selection. Based on the coding or marking indicating the type of transmission needed, the appropriate transmission would be selected either manually or by an automated system from an inventory comprising a variety of transmissions having different reduction ratios and assembled into the operator.

This modular assembly concept is particularly advantageous over existing manufacturing methods. In current manufacturing practices, a different operator is made for each application, thus requiring a variety of assembly lines and a number of different workers or mechanized assembly machines performing similar tasks on different lines. By assembling the operator

10

of the present invention in a modular fashion, the same basic components can be used for each operator and the certain components can be selected from a given variety to tailor the operator to a given application. The stop member

132

and the transmission

150

are the two components which often have the most varied requirements and hence are best suited for this modular assembly concept. Also, certain components of the camming structure

108

can widely vary for given applications, and thus modular assembly principles are also well suited for assembling the camming structure

108

, as will be appreciated below.

Because the planetary gear arrangement in the present transmission

150

affords such a high reduction ratio in a small amount of space, it is possible to use the motor

116

and transmission

150

together without the output drive assembly

52

and directly connect an operator output member similar to output member

30

to the transmission output so that the output member, the transmission, and the motor all share a common axis. The output member can then be connected directly to the door coaxially with the door axis. It is believed that there have been no commercially successful axially mounted operators on the market because of the space concerns related to achieving the appropriate reduction ratio in the transmission. The present transmission achieves such a superior reduction ratio per volume occupied that it is possible to utilize the door operator in such an axially aligned manner.

Further, the present transmission

150

also provides the door operator

10

with sufficient flexibility to be utilized with sliding doors as a result of its advantageous reduction ratio per unit volume. For use with a sliding door, the motor

116

and the transmission

150

would again be used without the output drive assembly

52

and an output member similar to output member

30

would again be connected directly to the transmission. The directly connected output member can then be connected to a pulley (or have the pulley pre-connected thereto) which engages with a belt for driving the sliding door, as is conventional in sliding door operators. Rotation of the output member rotates the pulley to drive the belt to affect door sliding. The direction of the output member rotation could be reversed simply reversing the polarity of the current being delivered to the motor

116

, thus sliding the door in the opposite direction.

Referring now to

FIGS. 4 and 7

, the motor

116

and the transmission

150

are assembled together within the motor/transmission sleeve

120

with the transmission facing out the forward end of the sleeve

120

and the motor

116

facing out the rear end of the sleeve

120

. The motor has a pair of axially extending fasteners

196

which extend through the entire length thereof and have forward threaded end portions

198

protruding from the front wall

117

. The forward end portions

198

are received within a pair of threaded bores (not shown) which are formed in the rear cover

160

of the transmission

150

. The fasteners

198

can be tightened with a screwdriver or a similar tool suitable for fastener rotation to secure the motor

116

to the transmission

150

. The housing

12

has an opening at the rearward end thereof that provides access to the interior thereof. The motor

116

is positioned within the housing adjacent to the opening

199

such that the fasteners

198

can be accessed through the opening

199

for selective manipulation thereof for tightening and loosening the same. In the illustrated embodiment, the motor metering device

136

may have overall diametric dimension that is small enough to not interfere with access to the fasteners

198

by a screwdriver or the like. Alternatively, the metering device

136

may have an overall diametric dimension large enough to cover the fasteners

198

and obstruct as to the same. In that event, the metering device

136

needs to be removed prior to accessing the fasteners

198

. The motor

116

and opening

199

are configured with respect to one another (a) to enable the motor

116

to be moved out of the operating position thereof outwardly through the opening

199

without disassembling the housing

12

and (b) to enable the motor

116

to be moved inwardly through the opening

199

back into the operating position thereof.

In the operative position thereof within the housing, the motor

116

is coupled to the operator output member

30

via the transmission

150

, the motor output member, and the output drive assembly

32

such that operation of the motor affects rotation of the operator output member

30

. To remove the motor

116

from the operative position thereof for servicing such as repair or replacement or inspection, the technician opens the header

508

by removing the face panel

510

thereof and then manipulates the fasteners

198

in a motor releasing manner by rotating the same in an untightening direction through the opening

199

to disengage the same from the transmission

150

. Then, the technician removes the motor

116

from the operative position thereof by withdrawing the same from the sleeve

120

and housing

12

through opening

199

and moves the same out from the header

508

. The motor

116

can then be serviced by inspecting the same to determine its operational condition and then as needed either repair the motor

116

, reposition the motor

116

back in the operative position thereof, or provide a replacement motor

116

and position that in the operative position. If needed, the technician may disconnect the motor

116

from its power supply and/or its controller. To move the motor

116

or its replacement back into the operative position, the technician inserts the motor

116

or replacement motor into the housing

12

and sleeve

120

through the opening

199

so that the fasteners

198

align with the bores on the transmission

150

for insertion therein. The technician then selectively manipulates the fasteners

198

in a motor securing manner to secure by rotating the fasteners in a tightening direction to threadingly engage fasteners

198

within these bores to secure the motor

116

in the operative position thereof and reconnects the motor

116

or replacement motor to the power supply and/or controller. Finally, the technician replaces the face panel

510

of the header

508

and fastens the same by suitable fasteners or snap clips.

Thus, the invention may be considered to provide a method for servicing a door operator comprising: (a) releasing an installed motor

116

by manipulating the fasteners

198

in a motor releasing manner; (b) moving the released motor out of the operating position thereof outwardly through the opening

199

without disassembling the housing

12

; providing a reinstallation motor, the reinstallation motor and the opening

199

being configured with respect to one another to enable the reinstallation motor to be moved inwardly through the opening

199

to position the reinstallation motor in the operating position thereof within the housing

12

interior; moving the reinstallation motor inwardly through the housing opening

199

to install the reinstallation motor in the operating position within the housing

12

interior such that the reinstallation motor is coupled to the operator output member

30

such that operation of the reinstallation motor rotates the output member

30

so as to move the door panel between the open and closed positions thereof; and securing the reinstallation motor in the operating position within the housing interior.

Providing the reinstallation motor may be accomplished by servicing the released motor

116

and then reinstalling the same as the reinstallation motor. During such servicing the technician may simply repair the released motor. Also, the technician may simply inspect the motor to determine its operation condition. If such inspecting results in a determination that the motor does not require repair, that would conclude the servicing. If such inspecting reveals that the motor

116

requires repair, the servicing may further comprise repairing the motor

116

to provide the reinstallation motor.

Providing the reinstallation motor may also comprise providing a replacement motor similar, but note necessarily identical, to motor

116

. This may be done simply to replace the motor

116

or as a result of inspecting the released motor

116

and making a determination that the released motor is damaged and should not be repaired (either because it is impossible or impractical).

This arrangement provides for easy removal and maintenance of the motor

116

. Specifically, the motor

116

can be removed from the operator

10

for maintenance or replacement without having to dismount the operator

10

from above the door. In conventional operators, the entire operator had to be removed and disassembled to service the motor. With the present arrangement, such steps are obviated, thus simplifying maintenance and reducing overall maintenance time, which in turn reduces overall maintenance costs.

An annular spring force adjusting member

200

is threadingly engaged with a threaded rear end portion

202

of the motor/transmission sleeve

120

. A coiled door return compression spring

204

is slidably mounted over the exterior of the sleeve

120

with a rear volute

206

of the spring

204

engaging a forwardly facing spring bearing surface

208

of the spring force adjusting member

200

. A rearward annular ring

210

which comprises a portion of the camming structure

108

is slidably mounted over a forward end portion of the sleeve

120

and a spring bearing surface

212

thereof is engaged with the forward volute

214

of the spring

204

. When the operator

10

is assembled, the two apertures

216

on the ring

210

receive the rearward end portions of the connecting rods

112

and a forwardly protruding portion

218

of the front transmission cover

156

is received inside the receiving portion

94

on the lower housing shell

24

. A pair of radially aligned fasteners

220

are inserted through apertures

222

on the receiving portion

94

and receiving in threaded bores

224

on the front transmission cover

156

to secure the transmission

150

(and hence the motor

116

fastened thereto) in place. In this position, the spring

204

is stressed between the forwardly facing and rearwardly facing spring bearing surfaces

208

,

212

of the spring force adjusting member

200

and the annular ring

210

, respectively. Mounting the spring

204

about the exterior of the motor

116

and the transmission provides the operator

10

with an overall increased compactness and better utilizes space in comparison with known operators.

As can be best seen in

FIGS. 12

a

and

12

b

, the forward end portion of the cam structure

108

has a cam member

226

that provides a contoured cam surface

228

. An upper plate

230

, which is not shown in

FIGS. 12

a

and

12

b

, is placed over the cam member

226

and is shown in the other Figures. The cam surface

228

engages the cam follower

106

so that the cam follower

106

rides along the cam surface

228

to cam the cam structure

108

in a cam travelling direction radially away from the operator output member axis as the output member

30

is rotated under power from the motor

116

in a door opening direction. As a result of the cam structure

108

being cammed radially away from the output member axis, the annular ring

210

slides rearwardly in the cam travelling direction over the motor/transmission sleeve

120

to compress the spring

204

between the spring bearing surfaces

208

,

212

. When the power being delivered to the motor

116

ceases, the return spring

204

extends to move the cam structure

108

in the cam travelling direction back towards the output member axis so that the cam surface

228

thereof cams the cam follower

106

so as to drive the output member

30

is a door closing direction.

It should be noted that the spring

204

applies force to the output member

30

through the cam follower

106

and the drive plate

54

in the door closing direction rather than through a gear arrangement whereas the motor

116

and transmission

150

drive the output member

30

through the gear arrangements of the output drive assembly

52

and the transmission

150

. This “split path” force transmission—transmitting door opening forces via a geared path and transmitting door closing forces via a separate path—is advantageous because it reduces wear and tear on the gear teeth which will eventually produce backlash or loose play between intermeshed gears. In conventional rack/pinion arrangements, forces which open the door panel

506

are transmitted from the motor via the geared rack/pinion arrangement and the forces which close the door are transmitted from the return spring also via the same geared rack/pinion arrangement. Thus, the gear teeth wear down more rapidly in the conventional arrangement because both the opening forces and the closing forces are transmitted through the same gear teeth. In contrast, the present arrangement reduces wear and tear on the teeth of the transmission

150

and the output drive assembly

52

because forces are transmitted through the gears thereof only during the door opening stage of the door panel's movement. The door closing forces are transmitted via the camming structure

108

and cam follower

106

so that the load is not being carried by the gears during this stage of the door panel's movement. Although the radially offset cam follower/camming structure arrangement is disclosed and considered the most suitable arrangement, other split path arrangements may be used to relieve the door closing load from the gears which drive the door in the opening direction.

The contoured shape of the camming surface

228

provides an angled portion

229

that extends at an angle with respect to the cam travelling direction that allows the spring

204

to apply a spring force to the offset cam follower

106

which is non-linear throughout the door's path of travel. Specifically, as the cam follower

106

cams along the angled portion

229

, the force stored in the spring or applied thereby varies non-linearly as a function of the slope of the angled portion

229

with respect to the cam travelling direction. As the slope approaches zero, the force the less change in compressed/relaxed spring length per degree of output member

30

rotation. Likewise, as the slope approaches ninety degrees, the more change in compressed/relaxed spring length per degree of output member

30

rotation.

Because the cam surface

228

has an angled portion

229

, as the follower

106

cams along the angled portion

229

, forces the transverse to the cam travelling direction will be created. One way to prevent the cam structure

108

from simply moving transversely with respect to its travelling direction is to provide a pair of guiding members

300

fixed to the interior of the housing

12

that slidably engage to opposing sides of the cam member

110

. This functions to transmit these transverse forces to the housing

12

itself.

To alleviate the transfer of forces to the housing

12

, the driving member has a force receiving member

302

mounted concentrically on its rotational axis and the cam member

110

has a notch

304

extending through the central underside thereof in the cam travelling direction. The notch

304

provides a pair of force transmitting surfaces

306

the engage opposing sides of the force receiving member

302

to transmit the transverse forces thereto and alleviate force transmission to the housing

12

via guide members

300

.

The graph of

FIG. 13

illustrates a number of traces showing the door closing forces applied by the spring throughout the door panel's path of travel in which the door panel's position is shown in degrees. Referring to the top trace on the graph, the highest door closing force is applied at the door's fully closed position (0 degrees from closed), then decreases to its lowest door closing force around 35 to 40 degrees from filly closed, and increases to its second highest closing force is applied between 90 and 100 degrees from fully closed. This force profile is selected for outside door applications where the highest closing forces are needed at fully closed and near 90 degrees open, the two positions at which higher forces are needed to overcome wind forces. Specifically, the wind forces are higher near 90 degrees because of the increased effective surface area of the door panel

506

and near fully closed because of both the pressure differential created as a wind blows by the door panel

506

and draws air outwardly from the building interior through the door opening and the resistance of the seals between the door panel

506

and its frame

504

. A high force is also needed rear fully closed in order to overcome friction force of the door seals.

With conventional operators, this non-linear force profile could not be achieved because the door closing force would always be lower near fully closed as a result of the spring extending towards it neutral position. Further, because certain building codes specify maximum door closing forces, a satisfactory door closing force near the fully closed position cannot be achieved with a conventional operator simply because the maximum door closing force is limited and the door closing force will always decrease from the maximum towards the fully closed position as a result of its linear nature.

It should be understood that the contour of the cam surface

228

can be manipulated to provide desired door force profiles for various applications. In fact, it is contemplated within the present invention to pre-fabricate a variety of camming members

226

with cam surfaces

228

of varying contours or profiles and to assemble the camming members

226

into the operator during assembly in a modular fashion in accordance with discussion set forth above. Depending on the specifications or other information which is marked or otherwise encoded on the operator, the assembly worker or an automated machine selects the appropriate camming member

226

and mounts the same to the camming structure

108

and then assembles the camming structure

108

into the operator. Thus, a number of operators which are designed to provide different door closing forces with varying profiles can be assembled on a single assembly line. Combining the modularity of the camming member

226

with the modularity of the transmission

150

and the stop member

32

creates great manufacturing flexibility by allowing a wide variety of operators which meet different specification to be assembled using the same base components and increases overall manufacturing efficiency.

The profile of the cam surface

228

may be asymmetrical with respect to the cam travelling direction so that the force transmission provided by the camming action is different in the opposite opening directions of door movement from the closed position thereof.

The camming feature discussed herein may be provided by providing an eccentric driver member and a cam structure with one or more cam followers providing the cam surface thereof as shown in U.S. Pat. No. 5,193,647, the entirety of which is hereby incorporated into the present application by reference.

Another advantage of the camming surface

228

illustrated is that it is symmetrical in a plane taken perpendicularly to the operator output member axis. This symmetry provides the same door closing force profile regardless of in which direction the door is being opened to allow the door to function in a “non-handed” manner in conjunction with the reversible motor

116

. In the door operator art, the door operators are labeled either right or left handed depending on which direction they will open the door because the rack/pinion arrangements of these operators will only drive the door in one direction. The properly handed door operator must be selected prior to installation depending on the particular door opening direction desired. In contrast, the operator

10

of the present application can pivot a door in either a clockwise or a counterclockwise direction simply by reversing the polarity of the current being delivered to the motor

116

. Because the cam surface

228

is symmetrical, the door force profile will be substantially the same regardless of which direction the door is pivoted. Thus, there is no need to provide left and right-handed door operators because the door operator

10

of the present application can be utilized in either manner. This feature further increases manufacturing efficiency because only one type of door operator need be made, rather than two types which pivot doors in opposite directions. Furthermore, the swing of the door can later be reversed without having to remove the operator

10

and install a new one because all that needs to be done is to reverse the polarity of the current being delivered to the motor

116

as described above. A switch in the controller could be provided to perform this function.

A variation on this non-handed or bidirectional feature would be locating switches on either side of the door, whether the switch be manually operated by hand, a pressure plate which senses when a person has stepped on the plate, or some other sensor, such as an electronic eye, and connecting the switches to the controller such that actuation of either switch causes the door to swing away from the side of the actuated switch. In this arrangement, the door would always swing away from the person passing through it. The use of a coiled compression spring in the present door operator

10

is advantageous in this context because it allows the door to be spring returned to the closed position from either direction. Some known door operators have a clock spring engaged with the output member to provide the closing force. The problem with this arrangement is that a suitable return force is applied in only one direction because the spring is compressed in only one rotational direction. In the present operator

10

, the compression spring

204

will be compressed no matter which direction the door rotates and hence the spring

204

will apply a door closing force in either direction to move the door towards and into its full closed position.

The use of a linear compression spring is also advantageous because it allows the door to be spring returned even when it has been pushed beyond its fully closed position in an opening direction opposite the direction which the motor

116

drives the door. The ability to open opposite the direction in which the motor drives the door is referred to in the operator art as “breakout” and the ability of the spring to close the door after breakout if referred to as “return from breakout”. Many building codes require breakout in door operators so that the doors can be manually opened opposite the intended opening direction during emergency situations. This return from breakout is advantageous because it ensures that the door will close after breakout has occurred. With operators which incorporate clock springs, the return force is typically insufficient to return the door from breakout and thus the door will remain open until manually closed.

The “valleyed” or concave profile of the U-shaped cam surface

228

of the camming member

226

also allows the door operator

10

to be “self-centering” as a result of the spring being in its most extended condition when the cam follower

106

is positioned in the U-shaped center portion

234

of the camming surface

228

, as shown in

FIG. 12a

(i.e., the portion where the legs of the U-shape converge). As a result, the output member

30

is biased into its fully closed position because the additional force in one of the opposing opening directions would be required to compress the spring

204

.

The spring force adjusting member

200

rotates for axial movement along the threaded end portion

202

of the sleeve

120

. As the member

200

is rotated to move further axially inwardly in the longitudinal direction of the spring, the spring

204

is further compressed and will thereby apply a higher door returning force to the drive plate

54

and the output member

30

. As the member

200

is rotated to move further axially outwardly, the spring is allowed to extend and will thereby apply a lower door returning force. This adjustablity provides the operator

10

with the flexibility to have the door return forces thereof easily adjusted. Thus, the same operator can be adjusted from a high energy operator to a low energy operator simply by rotating the adjusting member

200

to move the member

200

rearwardly along the rear end portion

202

through its range of adjusting positions. Finer adjustments between high and low energy can be made to accommodate varying door force specifications. Specifically, the range of adjustments is infinite as a result of the threaded relationship. Further, the wide adjustability range allows the same operator to be used for different applications, thereby allowing the manufacturer to produce one door operator for a wide range of needs. This features further enhances the operator's flexibility when used in conjunction with the modular assembly components discussed above.

As can be appreciated from this construction, the present invention can be said to provide a method for adjusting spring force in a door operator comprising moving the spring force adjusting member

200

in the longitudinal direction of the spring

204

to a selected position within its range of adjusting positions such that the spring

204

is stressed (compressed in the illustrated embodiment) to an extent determined by the selected position of member

200

. This adjusts the amount of spring force that the spring applies to the operator output member

30

during spring driven rotation thereof. Moving the adjusting member

200

may be done by rotating the adjusting member

200

. To access the adjusting member

200

, a technician may have to remove the upper half of the housing

12

prior to moving the same and thereafter replace the upper half of the housing

12

in its original position. To do this, the operator

10

may have to be disconnected and removed from the header of the door assembly.

FIGS. 15

a

through

15

c

illustrate a door operator

400

having an alternative arrangement for the adjustable stop members thereof. The swing door operator

400

may be of any type of door operator and as illustrated has a construction like operator

10

discussed hereinabove. The operator

400

has an operator stop member, generally indicated at

402

, mounted to said output member

30

and a fixed operator stop member, generally indicated at

404

mounted to the housing

12

. The operator stop member

402

is adjustably movable relative to the output member

30

to provide the range of relative movements and comprises a pair of spaced apart stop members

406

,

408

that are each adjustably movable relative to the output member

30

generally circumferentially with respect to the axis thereof. The fixed stop member

404

comprises a pair of spaced apart stop members

410

,

412

fixed to the underside of the housing

12

adjacent the output member

30

.

A mounting structure

414

is fixed to said output member

30

and a pair of fasteners

416

,

418

are constructed and arranged to fix the spaced apart stop members

406

,

408

to the mounting structure

414

. The fasteners

416

,

418

are constructed and arranged to release the spaced apart stop members

406

,

408

for adjusting movements thereof. Specifically, each of the spaced apart stop members

406

,

408

has an elongated slot

420

,

422

extending generally circumferentially with respect to the rotational axis of the output member

30

, the mounting structure

414

has a pair of spaced apart threaded bores (not shown) and the fasteners

416

,

418

are each threaded for receipt in said bores. The threaded fasteners

416

,

418

are received through said elongated slots

420

,

422

and in threaded relation within said threaded bores to fixed said spaced apart stop members

406

,

408

to said mounting structure

414

. The mounting structure

414

also has a plurality of engaging teeth

424

thereon and each of said spaced apart stop members

406

,

408

has a plurality of engaging teeth

426

,

428

engaged in intermeshing relation with the engaging teeth

424

of said mounting structure

414

to prevent relative circumferential movement of said spaced apart stop members

406

,

408

relative to said mounting structure in cooperation with said fasteners

416

,

418

. To adjust the positioning of one of the spaced apart stop members

406

,

408

, the appropriate fastener

416

,

418

is untightened to the extent necessary to permit the teeth

426

,

428

to be disengaged from mounting structure teeth

424

. Then the stop member

406

,

408

is moved circumferentially to the desired position and the fastener

416

,

418

is retightened to re-engage the teeth sets

424

,

426

,

428

and fix the stop member

406

,

408

in place.

The term swing door operator is used in the specification and in the appended claims to cover operators that pivot a single door panel (including balanced door panels) and operators that pivot the proximal panel of a bi-fold or tri-fold door panel assembly. No aspect of the invention is to be limited solely to single panel door panel arrangements.

The present invention is intended to cover arrangements wherein the motor provides door movement in the opening direction thereof and the spring structure provides door movement in the closing direction thereof; arrangements wherein the spring structure provides door movement in the opening direction thereof and the motor provides door movement in the closing direction thereof; arrangements wherein the motor provides door movement in the opening direction thereof and then the motor is reversed to assist the spring to provide door movement in the closing direction thereof; and arrangements wherein the motor assists the spring to provide door movement in the opening direction thereof and then the motor is reversed to provide door movement in the closing direction thereof without assistance from the spring structure. Certain aspects of the invention may be practiced irrespective of whether a spring structure is used in the operator at all.

The present invention may be applied to high energy door applications wherein a plurality of safety sensors are used to detect the presence of persons and objects in the path of a moving door panel. The present invention may be applied to low energy applications where such sensors are not required.

The foregoing specific embodiment has been provided to illustrate the structural and functional principles of the present invention and is not intended to be limiting. To the contrary, the present invention is intended to encompass all modifications, substitutions, and alterations within the spirit and scope of the appended claims. For example, although an operator which opens the door under motor power and closes it by spring force is disclosed in the present application, it is to be understood that the principles of the present invention may be applied to a door operator which opens the door under spring force and closes it under motor power. Other such variations on the features and arrangements disclosed herein will be readily understood by those in the art and are encompassed within the scope of the appended claims.

Number	Name	Date	Kind
1927559	Talen	Sep 1933	A
1986639	Konn	Jan 1935	A
3087720	Catlett et al.	Apr 1963	A
3237932	Catlett et al.	Mar 1966	A
3422704	Catlett et al.	Jan 1969	A
3425161	Catlett et al.	Feb 1969	A
3457674	Catlett et al.	Jul 1969	A
3605339	Catlett et al.	Sep 1971	A
3625328	Carli	Dec 1971	A
3668737	Tillmann	Jun 1972	A
3675370	Catlett	Jul 1972	A
3760455	Berry et al.	Sep 1973	A
3834081	Catlett	Sep 1974	A
4045914	Catlett	Sep 1977	A
4134231	Daugirdas et al.	Jan 1979	A
4220051	Catlett	Sep 1980	A
4231192	Daugirdas et al.	Nov 1980	A
4333270	Catlett	Jun 1982	A
4599824	Mitsuhashi et al.	Jul 1986	A
4660250	Tillman et al.	Apr 1987	A
4727679	Kornbrekke et al.	Mar 1988	A
4744125	Scheck et al.	May 1988	A
4785493	Tillmann et al.	Nov 1988	A
5193647	O'Brien, II	Mar 1993	A
5221239	Catlett	Jun 1993	A
5386885	Bunzl et al.	Feb 1995	A
5680674	Guthrie	Oct 1997	A
5687507	Beran	Nov 1997	A
5913763	Beran et al.	Jun 1999	A
6134835	Krupke et al.	Oct 2000	A

Number	Date	Country
1270355	Apr 1972	DE
3202930	Aug 1983	DE
544254	Jun 1993	EP
2707695	Jun 1993	FR

Automatic door assembly and door operator therefor

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Parent Case Info

US Referenced Citations (30)

Foreign Referenced Citations (4)

Non-Patent Literature Citations (1)

Provisional Applications (1)