Motor operated lock

A motor operated lock wherein the motor is translated when the motor shaft rotates, the motor shaft acting as the bolt of the lock and engaging or disengaging the door to lock or unlock the door. The motor is located on a fixed platform and is moved by the cooperation of a nut affixed to the platform and a threaded portion of the motor shaft. The assembly can be located inside or exterior the wall and can be adapted for easy removal. The motor direction and travel limits are controlled by appropriate electrical circuitry.

BACKGROUND OF THE INVENTION 
1. Field of the Invention 
The present invention relates to electrical locks used in entry and exit 
passages and other access controlled areas. 
2. Description of the Prior Art 
Electrically controlled locks are commonly used in many security 
applications. The flexibility provided by an electric lock assembly allows 
the opening and closing of the lock to be remotely controlled from a guard 
station to allow limited access to a facility. Additionally, use of an 
electric lock assembly can allow the time of access to be controlled using 
a time clock mechanism, as is common in bank vaults for instance. 
The two most common types of electric locks in use today are those that are 
magnet operated and those that are solenoid operated. The magnetically 
operated types use a magnetic field producing apparatus on a fixed portion 
of the door frame and a magnetically attracted material on the door so 
that when the magnetic field is energized, the door is locked due to the 
magnetic force and when the field is de-energized, the door is unlocked 
and can be freely opened. A magnetic lock therefore requires the constant 
use of a magnetic field and the involved heat and electrical current, to 
maintain the door in a locked condition. Additionally, should the power 
fail, the lock would be disabled and the door would be opened, allowing 
entry to the facility. 
The other common type of electrically operated lock is a solenoid type 
mechanism wherein the energizing of a solenoid either engages a bolt or 
disengages a bolt, thereby appropriately locking or unlocking the door. 
One major problem with a solenoid system is that the solenoid is not 
suitable for continuous duty use because it will overheat and therefore 
become inoperable after a certain period of time, generally measured in 
minutes. This condition is shown in U.S. Pat. No. 4,640,108 where a 
time-delay relay was included to de-energize the solenoid after 1.5 
seconds to preclude solenoid damage. This time period dramatically limits 
when the solenoid can be energized and the door can be in an open or 
closed position therefore effectively requiring constant attention by an 
operator to control the lock. 
U.S. Pat. No. 4,592,453 discloses a lock assembly using a clutch to allow 
door knob rotation to be transmitted to a latch assembly. A motor is used 
to engage and disengage dogs used to control the clutch for the coaxial 
transmission of the knob rotation. This is a cumbersome and complicated 
method and requires the use of a conventional bolt for locking the door to 
the door jamb. 
SUMMARY OF THE INVENTION 
The lock of the present invention uses a motor to drive a deadbolt into and 
out of a door. The motor is actuated in a first direction to cause a 
rotation of the motor shaft, which is then converted into a linear, 
translational motion which is in turn transmitted to the bolt which is 
projected through the door jamb and into the door. The travel of the 
deadbolt into the door is discontinued on the signal of a feedback switch 
connected to an appropriate moving member to sense when the lock is fully 
closed. When the lock is desired to be opened, the motor is actuated to 
run in a reverse direction and thereby withdraw the bolt from the door, 
into the door jamb and the wall. The withdrawal motion of the bolt is 
discontinued on the signal of a second feedback switch which senses when 
the bolt is sufficiently withdrawn to allow the door to be opened. 
In one embodiment, the motor itself actually slides along a path such that 
the motor shaft is the deadbolt. In this embodiment, the motor shaft 
contains a threaded portion which is connected to a nut having a fixed 
location to allow the motor to move transversely because the rotational 
motion of the shaft is converted to translational motion. The feedback 
switches indicate when the motor has reached the fully opened or fully 
closed position to disable the motor drive to prevent damage to the motor. 
The controls for the lock are designed such that the lock can preferably be 
opened only during certain intervals governed by timers and requiring the 
use of a second, secure switch to actually initiate opening of the lock. 
If the time period as indicated by the timers has expired, the lock 
automatically closes. 
The use of the motor overcomes any continuous duty cycle and power draw 
problems present in prior electrical locks because as the motor is not 
always in an energized condition, but is energized only during the travel 
of the bolt and not during holding periods, the power draw and energizing 
time are low.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
Referring now to FIG. 1, the letter L generally represents a lock according 
to the present invention. The lock L is mounted in a wall 12 and is used 
to lock a door 10. A frame 18 is mounted inside the wall structure by 
means of brackets 34 to form a fixed frame onto which to mount the movable 
portions of the lock L. The frame 18 includes a vertical member 36 which 
is parallel to the door frame or jamb 13 and the door 10. The vertical 
frame member 36 contains a through-hole and has attached a fixed nut 20, 
the opening of the nut 20 being coaxial with the opening or through-hole 
in the vertical member 36. The nut 20 is rigidly attached by welding, 
brazing or other technique to the vertical member 36 so that it cannot 
rotate. A motor 14 and if desired, depending on motor 14 rotational speed 
and nut 20 pitch, a gear reducer or speed reducer 16 attached to the motor 
14, are located on the frame 18 in a slidable configuration. The output 
shaft 17 of the gear reducer 16 contains a threaded portion 22 and a 
smooth portion 24. The threaded portion 22 is adapted to be mated with the 
nut 20 to provide a rotational to translational motion transformation. The 
smooth end 24 is the bolt which is inserted into a door cavity 28 through 
a striker plate 26. 
When the motor 14 is energized, the output shaft 17 rotates. The 
cooperation between the nut 20 and the threaded portion 22 of the shaft 
then causes the motor 14, gear reducer 16 and shaft 17 to slide or 
translate along the frame 18 alternately engaging and disengaging the 
smooth end 24 and the door 10. 
Located in appropriate positions on the frame 18 are a closed switch 30 and 
an opened switch 32. The closed switch 30 indicates when the motor 14 has 
moved to the fully closed position and the motor 14 can be de-energized, 
while the opened switch 32 indicates when the motor 14 has reached the 
fully opened position and the motor 14 can be de-energized. While in the 
illustrated embodiments the opened and closed switches 30, 32 are shown 
mounted to the frame 18 and activated by direct contact with the motor 14, 
it is understood that the switches can be remotely mounted and activated 
by the appropriate linkages or can be non-contact switches, such as Hall 
effect switches, the switches only needing to provide a feedback signal 
indicating when the motor 14 has reached the fully open or closed 
position. 
The lock L in FIG. 1 is shown in the opened position. If the motor 14 is 
energized, the cooperation of the fixed nut 20 and the threaded shaft 22 
cause the motor 14 to slide transversely and the smooth shaft 24 to 
project into the door cavity 28. The motor 14 continues to slide 
transversely until it is deactivated due to the action of the motor 
engaging the closed switch 30. 
To open the lock L, the motor 14 is energized to rotate in the opposite 
direction. The cooperation of the nut 20 and the threaded shaft 22 would 
slide the motor 14, withdrawing the smooth shaft 24 from the door 10 into 
the wall 12. The motor 14 continues to slide until it is deactivated due 
to the action of the motor 14 engaging the opened switch 32. 
Alternatively, the lock L can have the motor components mounted externally 
of the wall to allow the lock assembly to be rapidly removed in case of an 
emergency. Two end plates 42,44 are used in conjunction with connecting 
bearing rods 40 to perform the equivalent function of the fixed structure 
18 in FIG. 1. The bearing rods 40 can be fastened to the end plates 42,44 
by means of self-locking nuts or other suitable means, to allow ease of 
assembly and maintenance. The nut 20 is located on the fixed end plate 42 
and cooperates with the threaded shaft 22 to allow the motor to slide 
transversely along the bearing rods 40 as necessary. The deadbolt 46 is 
L-shaped, projects through one wall 38 and is of sufficient length to 
allow the deadbolt 46 to be inserted into the door cavity 28. Thus the 
lock L can be mounted at variable distances from the door 10 by means of 
longer deadbolts 46, allowing easier placement of the lock L. 
The embodiment shown in FIG. 4 can easily be removed in case of an 
emergency. The embodiment of FIG. 4 does not show the motor 14, shaft 17 
or switches 30, 32 for reasons of clarity. A base plate 202 is mounted to 
the wall to form a fixed reference. The base plate 202 preferably includes 
a flat portion 220 and rolled sides 222. The flat portion 220 includes a 
hole 204 to be used in conjunction with a pin 210 to lock a motor frame 
218 to the base plate 202. 
The motor frame 218 is preferably a U-shaped piece having end plates 42, 44 
and a bottom 216. Two bearing rods 40 span the frame 218 and are attached 
to the end plates 42, 44 in a similar manner as the embodiment of FIG. 2. 
A through-hole 208 is located in one end plate 42. The frame 218 includes 
cutout corners 214 to allow the bottom 216 to mate with the rolled sides 
222 of the base plate 202. In this manner the frame 218 can be slid into 
and out of the base plate 202 as desired. 
The bottom 216 contains a hole 206 designed to cooperate with the pin 210 
and the hole 204 in the base plate 202. When operation of the lock L is 
desired, the pin 210 is inserted through the holes 204, 206, thereby 
fixing the motor frame 218 and the base plate 202 in a fixed relationship, 
so that the smooth shaft 24 or deadbolt 46 can be driven by the motor 14 
into the door 10 and the lock L operated normally. If the lock L is in a 
closed position and an exit is needed, for example in the case of an 
emergency condition such as a fire or if the electrical power has failed, 
the pin 210 can be pulled and the motor frame 218 removed from the base 
plate 202, thus removing the smooth shaft 24 or deadbolt 46 from the door 
10. When normal operation is desired, the motor frame 218 is slid into the 
base plate 202 and the pin 210 is reinstalled. 
The motor 14 is a reversible motor to allow the lock L to be opened and 
closed. For this reason, it is necessary to provide control logic (FIG. 3) 
to energize the appropriate opening and closing leads of the motor 14 and 
to shut off power to the motor 14 when the motor has reached the 
appropriate travel point and the lock L is fully closed or fully opened. 
The direction of movement is controlled by the use of a direction relay 100 
having a set of normally opened contacts 102 and a set of normally closed 
contacts 104 configured in a single-pole, double-throw or Form C 
configuration. One relay terminal 101 and the central contact 108 are 
connected to a suitable voltage source 106. The voltage source can be 
alternating current or direct current as necessitated by the motor design. 
The other relay terminal 103 is connected to ground through a parallel set 
of switch contacts, one set being time clock contacts 110 and the other 
set being exit timer contacts 112. The time clock contacts 110 are 
normally open and are closed only during time-controlled intervals as 
determined by the time clock. The time clock is used to provide intervals 
where the building can be reentered from the outside, with no one inside. 
Preferably, the time clock is a 24 hour battery driven time clock or 
battery backed-up time clock which allows variable set points of varying 
intervals so that the lock L will be able to be opened at certain preset 
times. The exit timer contacts 112 are normally open and are connected to 
an exit timer which has a sufficient time delay once energized to allow a 
person to exit the door and to allow sufficient time for other necessary 
items which the person might be carrying to be removed without having the 
lock L closing while the door 10 is in the open position. 
When the relay 100 is de-energized, the lock closed position, the normally 
closed contact set 104 connects the voltage source 106 to the closed 
switch 30. The closed switch 30 is located in a physical relationship to 
the motor 14 such that the switch 30 is closed until the motor 14 has 
reached the fully closed position, at which time the closed switch 30 
opens, thereby disconnecting power to the motor 14 and ending the motor 14 
travel. The closed switch 30 thus performs a feedback function to indicate 
motor position. When the relay 100 is not energized, the logic 
automatically causes the motor 14 to drive the lock L closed, so that the 
lock L normally rests in the closed position. 
When either the time clock contacts 110 or exit timer contacts 112 are 
closed and therefore relay 100 is energized, the normally opened contacts 
102 are closed and electrical power is transmitted through deadbolt switch 
114, if closed, and the opened switch 32 to the open winding of the motor 
14. The opened switch 32 performs in a like manner to the closed switch 30 
in that it is normally closed when the motor 14 is not in the fully opened 
position, and opens when the motor 14 is in the fully opened position, 
thereby preventing damage to the motor 14 and the lock L. 
The deadbolt switch 114 is positioned in series with the opened switch 32 
to provide additional security. If the deadbolt switch 114 were not 
present, the lock L would be opened whenever the exit timer contacts 112 
or the time clock contacts 110 were closed. The use of the deadbolt switch 
114 allows the actual opening of the lock L to be performed only when 
passage through the door 10 is desired. Preferably, the deadbolt switch 
114 is a switch which is key activated and can be combined with a standard 
deadbolt lock for added security. 
When both the deadbolt switch 114 and the opened switch 32 are closed, and 
the relay 100 is in the open position, the motor 14 will be energized to 
open the lock L. The motor 14 will travel until it is in the fully opened 
position at which time the opened switch 32 stops the travel of the motor 
14. The motor 14 will stay in the fully opened position until both the 
exit timer 112 and the time clock contacts 110 are opened and the relay 
100 returns to the de-energized or close position. At this time, the lock 
L begins its automatic closure and operates as previously described. 
An optional override switch 116 is shown having a pair of normally opened 
contacts. The first set of contacts 118 is connected in parallel with the 
timer contacts 110, 112 to energize the direction relay 100. The second 
set of contacts 120 is used to parallel the deadbolt switch 114 so that 
hitting only a single switch is required to open the lock L. The override 
switch 116 can be used to open the door to allow guests or other visitors 
to enter the building without having to actuate the exit timer, which has 
a preferable time limit of 5 minutes. Additionally, use of the override 
switch 116 allows the opening of the door without the use of the deadbolt 
switch 114 and any key associated with it, eliminating this burden. 
While there is only one control circuit shown for the lock L, it is 
understood that the various timer switches and deadbolt switches could be 
operated by various means, such as radio-controlled switches, 
magnetically-operated switches and other devices well known to those 
skilled in the art. Additionally, the shown components are 
electromechanical but it is understood that electronic equivalents could 
be used to duplicate and further enhance the security and motion control 
logic. 
The foregoing disclosure and description of the invention are illustrative 
and explanatory thereof, and various changes in the size, shape and 
materials as well as in the details of the illustrated construction may be 
made without departing from the spirit of the invention, all such changes 
being contemplated to fall within the scope of the appended claims.