JP2013159957A - Electric lock - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an electric lock having enhanced safety with a plurality of electrically retractable dead bolts or the like and being capable of constructing a power supply part having many batteries without excessive enlargement of the external shape of the lock.SOLUTION: An electric lock including a main lock 2 and a sub-lock 3 is mounted in a cavity part for accommodation. The main lock 2 and the sub-lock 3 have a lock case in which a lock mechanism part, a motor 72, a control board, and power supply parts 35a and 35b are housed. The power supply part 35a of the main lock 2 includes four batteries 76 which are series connected to generate a direct current voltage of 6 volt. The power supply part 35b of the sub-lock 3 also includes four batteries 76 which are series connected to generate a direct current voltage of 6 volt. The power supply part 35a of the main lock 2 and the power supply part 35b of the sub-lock 3 are parallel connected to constitute a power supply having a voltage of 6 bolt and a capacity of the two batteries 76. The power supply is once inputted to the main lock-side. The power is supplied to the sub-lock-side 3 from the main lock-side through power lines 86 and 87.

Description

  The present invention relates to an electric lock that can be locked and unlocked by the power of a motor, a solenoid, or the like.

As is well known, the lock is a device for fixing the door so that it does not open. For example, the lock is provided with a cylinder, a key is inserted into the cylinder, and the cylinder is rotated with the key to be unlocked. That is, by inserting a key and rotating the cylinder, a dead bolt or the like is protruded from the lock case, and the dead bolt or the like is engaged with a strike made in the door frame and locked.
When unlocking, a key is inserted into the cylinder, the cylinder is rotated, and a dead bolt or the like is inserted into the lock case.

On the other hand, an electric lock that causes a dead bolt or the like to appear and disappear by power of a motor, a solenoid, or the like is known.
The electric lock is attached to a front entrance of an apartment house, for example, and locks and unlocks the entrance door (door) by remote control from each room.

Thus, although the electric lock was developed for the purpose of locking and unlocking by remote operation, in recent years, an electric lock for a so-called keyless locking system has been developed.
In other words, the conventional lock was unlocked by inserting the key into the keyhole and turning it as described above. However, it is troublesome to insert the key into the keyhole and use the key. There is a demand for unlocking the doors.
For example, a card is used instead of a key, and the card is unlocked by inserting or holding the card at a specific position. Alternatively, a remote control device is used instead of the key, and the lock is unlocked without using the key by operating the remote control device.

In recent years, the number of cases where two locks can be attached to one door has been increasing for the purpose of improving crime prevention.
As what implement | achieves this structure with an electric lock, there exist some which attached two dead bolts and a cylinder to one lock case.

JP 2010-37773 A JP 2009-185477 A

A keyless locking system is convenient, but cannot be locked with a card or the like when the power is lost.
That is, if it is a keyless locking system using a commercial power supply, it cannot be unlocked with a card or the like if a power failure occurs due to an earthquake or the like.
Here, many of the keyless locking systems can be locked and unlocked even with a key. However, since locking and unlocking with a card is more convenient, a user does not usually carry a key. For this reason, when a power failure occurs while going out, a locked-out state occurs and the room cannot be returned.
In a keyless locking system, the key is used less frequently, so the key is often lost. If a power outage occurs in such a state, it will not be possible to lock the doors, resulting in inconvenience.

On the other hand, there is a keyless locking system using a battery as a power source. In a keyless system using a battery, a battery box is built in the lock case, and the battery is stored in the lock case.
The keyless locking system using a battery as a power source gives the user a sense of security in that the card can be locked and unlocked even if the commercial power supply fails.
However, since the battery is a consumable item, the keyless locking system using the battery as a power source needs to be replaced periodically.
Here, although the operation | work which replaces | exchanges a battery is not a difficult operation | work for a user, it is a troublesome operation | work and the one where the cycle to replace a battery is as long as possible is good.
Therefore, the number of batteries stored in a large number of lock cases is increased, and the cycle for replacing the batteries is lengthened.

  However, if a large number of batteries are built in the lock, the external shape of the lock becomes large, and it becomes difficult to store the lock in the door. In particular, in a lock provided with a plurality of dead bolts, two sets of mechanisms for moving the dead bolts in the first place are necessary, so that the outer shape of the lock case is large. If a large number of batteries are built on top of this, the outer shape of the lock case will become very large, making it difficult to store in the door.

  Therefore, the present invention pays attention to the above-mentioned problems of the prior art, and has a large number of batteries without increasing the external shape of the lock by increasing the safety by providing a plurality of dead bolts and the like that appear and disappear by electricity. It is an object to develop an electric lock capable of constructing a power supply unit.

  The invention according to claim 1 for solving the above-described problem has a plurality of lock portions that have a power source and can be electrically opened and closed, and each of the plurality of lock portions is an independent lock case. The electric lock is housed, and each lock case has a power supply unit with a built-in battery, and the power supply units are electrically connected in parallel.

  The electric lock of the present invention has a plurality of lock portions, and these have independent lock cases. The battery is dispersed in a plurality of lock cases. However, in the electric lock of the present invention, since the power supply units are electrically connected in parallel, one power supply is configured as a whole.

  The power source is a motor, and the switching circuit of the motor of the plurality of lock portions is housed in a specific lock case, and the motors housed in other lock cases are controlled by the switching circuit housed in the specific lock case. (Claim 2).

  The lock case is an electric lock into which the lock case is inserted into the lock storage cavity formed inside the door from the insertion opening formed on the end surface of the door, and the lock case is based on the main body and the mounting posture. A lock part that protrudes upward or downward from the main body part, and the total height of the lock case that is the sum of the main body part and the protrusion part is higher than the length of the insertion opening, and the height of the main body part Is preferably lower than the length of the insertion opening (claim 3).

As for the electric lock of this invention, the height of the lock case which added the main-body part and the protrusion part is higher than the length of the opening for insertion. Therefore, since the lock case is large and has a high storage capacity, a power source such as a motor or a solenoid can be stored in the lock case.
On the other hand, the height of the main body excluding the protruding portion is lower than the length of the insertion opening, so that the end of the insertion opening can be turned around by inserting the lock case into the insertion opening while rotating. it can. Therefore, the site | part containing a protrusion part can be put in the cavity part for lock | rock accommodation.

  It is desirable that the main body of the lock case is substantially square and the protrusion is also substantially square.

  As for the main-body part of the said lock case, it is desirable for it to be a shape from which a part of square was missing.

  The electric lock of the present invention can construct a power supply unit having a large number of batteries without excessively increasing the outer shape of the lock. Therefore, the cycle for replacing the battery is long and it is easy to use.

It is a perspective view of the door which attached the electric lock of the embodiment of the present invention. It is an expansion perspective view of the keyhole periphery of the main lock employ | adopted with the door of FIG. It is a perspective view of the end surface part of the main lock and door which are employ | adopted with the door of FIG. It is a perspective view which shows a mode that the front cover of the main lock employ | adopted with the door of FIG. It is a front view explaining the external shape of the lock case of a main lock. It is a cross-sectional perspective view of the lock housing cavity and the insertion opening vicinity of the main body portion of the door of FIG. FIG. 2 is a cross-sectional view of the lock housing cavity and the insertion opening in the vicinity of the main body portion of the door of FIG. 1 and a front view of the main lock employed in the door of FIG. 1. It is explanatory drawing which shows a mode at the time of inserting a main lock in the main-body part of the door of FIG. It is sectional drawing which shows the state by which the main lock | rock was mounted | worn with the main-body part of the door of FIG. It is the perspective view which took out the power supply part of the main lock and sublock which are employ | adopted with the door of FIG. It is explanatory drawing which shows the electric power of the main lock and sublock of a door of FIG. 1, and the condition of transmission / reception of a signal by a perspective view. It is explanatory drawing which illustrates notionally the situation of the power and signal transmission / reception of the main lock and sublock of the door of FIG. It is explanatory drawing which illustrates notionally the relationship between the electric power part of the main lock of a door of FIG. 1, a sublock, a motor, and a control apparatus. It is a front view of the main lock of other embodiments of the present invention.

Embodiments of the present invention will be further described below.
An electric lock 1 according to an embodiment of the present invention includes a main lock 2 and a sub-lock 3.
As shown in FIG. 1, the main lock 2 and the sublock 3 are attached to the end surface 6 on the free end side of the door 5. That is, the door 5 has one side fixed to the door frame 11 by hinges 7 and 8, and the other end (end face 6 side) is a free end.
An electric lock 1 and a latch lock 12 are attached to the free end side. In the latch lock 12, the latch 14 is projected and retracted from a lock case (not shown) by operating the handle 13 in the same manner as known.

In the present embodiment, the latch lock 12 is provided at a position at an intermediate height of the door 5, and the main lock 2 of the electric lock 1 is provided thereon. A sub-lock 3 of the electric lock 1 is provided under the latch lock 12.
In short, the main lock 2 and the sub-lock 3 of the electric lock 1 are provided at the vertical positions with the latch lock 12 interposed therebetween.
In FIG. 1, members provided on the upper portion of the door 5 and the door frame 11 are sensors 9 and 10 that confirm whether or not the door 5 is closed. Actually, the sensors 9 and 10 are attached to the indoor side, but are drawn on the outdoor side for the convenience of illustration.

  A cylinder 20 is attached to each of the main lock 2 and the sub-lock 3 as shown in FIG. A detection box 21 as shown in FIGS. 1 and 2 is provided around the cylinder 20 attached to the main lock 2. The detection box 21 is provided with a switch 15. The detection box 21 has an antenna 16 built therein.

The main lock 2 and the sub lock 3 are mounted in a lock housing cavity 22 (FIG. 3) formed inside the door 5 in the same manner as a known lock.
The lock receiving cavity 22 is also referred to as an engraved hole, and an insertion opening 23 is provided on the end surface of the door 5. Then, as will be described later, the mechanism accommodating portion 37 of the lock case 30 such as the main lock 2 is inserted into the lock accommodating cavity 22 from the insertion opening 23.

As described above, the electric lock 1 is composed of the main lock 2 and the sub-lock 3, but the shape and dimensions of both are the same. Therefore, the shape and dimension of the main lock 2 will be described as a representative.
The main lock 2 has a lock case 30 as shown in FIGS. 3, 4 and 5, and as shown in FIG. 4, the lock mechanism portion 31, the power portion 32, and the control board 33a are provided in the lock case 30. And a power supply unit 35a.

The lock case 30 has a mechanism accommodating portion 37 as shown in FIGS. 3 and 4, and a decorative plate 36 is provided on one surface thereof.
The decorative plate 36 is a strip-shaped metal plate and is provided with an opening 39 through which the dead bolt 43 appears and disappears. The decorative plate 36 is provided with attachment holes 42 and 54 at the upper and lower positions with reference to the posture attached to the door.
The mechanism accommodating portion 37 is a housing provided with a mounting flange portion 38 (hereinafter sometimes simply referred to as a flange portion 38) on one surface, and includes a box body portion 40 and a front lid 41.
The flange portion 38 is a strip-shaped metal plate similar to the decorative plate 36 described above. Similar to the decorative plate 36 described above, the flange portion 38 is provided with an opening 45 through which the dead bolt 43 protrudes and attachment holes 46 and 47.
The flange portion 38 is provided with an opening 44 for taking out the power source portion 35.

The external appearance of the mechanism housing portion 37 observed from the front side is as if the two quadrangles were combined as shown in FIGS. 3, 4, and 5.
That is, the mechanism housing portion 37 of the lock case 30 has a shape in which a large rectangular main body portion 50 surrounded by a region X in FIG. 5 and a small rectangular protrusion 51 surrounded by a region Y are combined.
That is, there is a large rectangular main body portion 50, and a protruding portion 51 hangs down at a position on the lower side of the main body portion 50 and far from the flange portion 38.

  The lock case 30 has a quadrangular shape with the central portion of the attachment flange portion 38 as one side. That is, as shown in FIG. 5, the lock case 30 has a central portion excluding the vicinity of the upper and lower mounting holes 46 and 47 of the mounting flange portion 38 as one side 55, and another side 56 from the mounting flange portion 38 to the rear end side 52. Is a rectangle.

  Further, as shown in FIG. 5, the protrusion 51 of the lock case 30 has a lower region of the rear end side 52 as one side 57, and a region of about ½ of the length from the rear end side 52 to the mounting flange portion 38 on the other side. It is a rectangle with side 58.

In other words, the main body 50 of the lock case 30 is assumed to be a rectangle having a side 56 extending from the mounting flange 38 to the rear end side 52 as one side and a rear end side (including the side 57) 52 as the other side. It can also be said that this part is a missing shape.
That is, the main body portion 50 of the lock case 30 has a shape in which a rectangular missing portion 60 is provided in a rectangle having the side 56 from the mounting flange portion 38 to the rear end side 52 as one side and the rear end side 52 as the other side. It can be said.
The position of the missing portion 60 is a region on the lower side of the lock case 30 and close to the attachment flange portion 38.

Next, the dimensions of each part of the lock case 30 and the dimensional relationship of the lock housing cavity 22 will be described with reference to FIG.
As shown in FIG. 7, when the length of the insertion opening 23 of the lock housing cavity 22 is A and the total height of the mechanism housing portion 37 of the lock case 30 is B, the total height B (flange portion 38) of the lock case 30 is set. The total height excluding) is higher than the length A of the insertion opening 23.
That is, the length (B) of the rear end side 52 of the lock case 30 is longer than the length A of the insertion opening 23. In other words, the combined height (B) of the main body portion 50 and the protruding portion 51 of the lock case 30 is longer than the length A of the insertion opening 23.

  However, when viewed only in the main body 50, the height C of the main body 50 is shorter than the length A of the insertion opening 23. That is, excluding the protruding portion 51, the height C of the mechanism housing portion 37 of the lock case 30 is shorter than the length A of the insertion opening 23.

Further, the distance E between the root portion 62 on the insertion opening side 23 of the protruding portion 51 and the protruding end portion 63 of the lock case on the side far from both the root portion 62 and the insertion opening 23 is the same as that of the insertion opening 23 described above. Shorter than length A. That is, the length E obtained by obliquely measuring the root portion 62 of the projecting portion 51 and the corner portion (actually chamfered) away from the flange portion 38 of the main body portion 50 is the length of the insertion opening 23. Shorter than A.
The length F of the mounting flange portion 38 is longer than the length A of the insertion opening 23.

Next, the device accommodated in the lock case 30 will be described.
As described above, the lock case 30 includes the lock mechanism portion 31, the power portion 32, the control board 33a, and the power supply portion 35a (FIG. 4).

The lock mechanism portion 31 occupies a region excluding the upper portion of the main body portion 50 of the lock case 30 and incorporates a hub 70, a dead bolt 43, and an interlocking mechanism (not shown) for interlocking both.
By rotating the hub 70 of the lock mechanism 31, the interlocking mechanism is moved, and the dead bolt 43 can be moved in and out of the lock case 30.
Further, the lock mechanism unit 31 incorporates a sensor (not shown). The sensor detects the entry / exit of the dead bolt 43.

  The power unit 32 includes a motor 72 a and a gear train 73 built in a storage case 74, and is stored in the protruding portion 51 of the lock case 30. An output shaft 84 projects from the storage case 74 of the power unit 32. The output shaft 84 is connected to the hub 70 of the lock mechanism 31 by a connecting member 77. Therefore, when the motor 72a of the power unit 32 rotates, the connecting member 77 operates to rotate the hub 70. As a result, the dead bolt 43 appears and disappears from the opening 45 of the lock case 30.

The control board 33 and the power supply unit 35 are arranged so as to overlap in the same region.
That is, the control board 33a is provided at a position above the main body 50 of the lock case 30 and on the side of the front lid 41 (the front lid 41 is removed in FIG. 4). In the same region, a power supply unit 35a is provided at a position on the box body 40 side.

The control board 33a contains software for inputting and processing a sensor signal (not shown).
In the present embodiment, the control board 33a on the main lock 2 side and the control board 33b on the secondary lock 3 side have slightly different functions. That is, the control board 33a on the side of the main lock 2 has a function as a control device that controls the entire operation of the electric lock 1.
Therefore, a function for receiving a signal from the antenna 16 and processing it, and a switching circuit 85 (FIG. 13) for starting and stopping the motor 72 and for reversely rotating are incorporated.

  The power source unit 35a is a unit in which four AA batteries are accommodated. That is, the power supply unit 35 a has a battery case 75, and four AA batteries 76 are arranged in the battery case 75 side by side.

The battery case 75 can be pulled out as shown in FIG. 10 by removing the decorative plate 36. That is, the battery case 75 is inserted into the mechanism accommodating portion 37 from the opening 44 provided in the attachment flange portion 38 of the mechanism accommodating portion 37. On the other hand, since there is nothing in the decorative plate 36 corresponding to the opening 44, the opening 44 that is the insertion portion of the battery case 75 is normally closed by the back surface of the decorative plate 36.
Therefore, when the decorative plate 36 is removed, the opening 44 provided in the attachment flange portion 38 of the mechanism housing portion 37 is exposed, and the internal battery case 75 can be extracted.

Next, a method for attaching the main lock 2 and the sub lock 3 to the door will be described.
As described above, the main lock 2 and the sub-lock 3 are attached to the lock accommodating cavity 22 (FIG. 2) formed inside the door, similarly to the known lock.
The lock receiving cavity 22 communicates with the outside through an insertion opening 23 formed on the end face of the door. The insertion opening 23 has a rectangular shape, and screw holes 78 and 79 for attachment are provided above and below the opening 23.
The vertical length of the lock receiving cavity 22 is considerably longer than the length A of the insertion opening 23 as shown in FIG.

  In the main lock 2 and the sub lock 3 of the present embodiment, the overall height B of the mechanism accommodating portion 37 of the lock case 30 is higher than the length A of the insertion opening 23, but the lock case 30 itself has a distorted shape. For this reason, the mechanism accommodating portion 37 can be accommodated in the lock accommodating hollow portion 22 by turning around the protruding end portion of the insertion opening 23.

That is, first, as shown in FIG. 8, the protruding portion 51 of the lock case 30 is inserted into the insertion opening 23. Then, the base portion 62 of the protruding portion 51 is placed in the vicinity of the lower side protruding end 80 of the insertion opening 23, and the upper side of the lock case 30 is largely rotated as indicated by an arrow with the root portion 62 of the protruding portion 51 as the center. Here, in the present embodiment, the height C of the main body 50 of the lock case 30 is shorter than the length A of the insertion opening 23.
Further, the distance E between the root portion 62 on the insertion opening side of the protrusion 51 and the protruding end portion 63 of the lock case far from both the root portion and the insertion opening is longer than the length A of the insertion opening 23. short.
Therefore, the protruding end 63 of the lock case passes through the upper protruding end 81 of the insertion opening 23, and the main body 50 enters the lock receiving cavity 22.

Thereafter, the rear end portion of the cylinder 20 is inserted into a cylinder insertion hole 82 (FIG. 3) provided on the front surface of the door 5, and the cylinder 20 is engaged with the hub 70 of the main lock 2 and the sublock 3.
Further, the mounting flange portion 38 of the lock case 30 is screwed (not shown) to the insertion opening 23 together with the decorative plate 36 to complete the attachment of the main lock 2 and the sub lock 3.

Next, the signal path | route and electric power path | route of the electric lock 1 of this embodiment are demonstrated.
In the electric lock 1 of this embodiment, the on / off signal of the switch 15 provided in the detection box 21 and the received signal of the antenna 16 are input to the control board 33a on the main lock 2 side as shown in FIGS. . Further, the signal of the sensor provided in the main lock 2 is also input to the control board 33a on the main lock 2 side as shown in FIG. Further, the signal of the sensor provided on the side of the secondary lock 3 is once input to the control board 33b on the side of the secondary lock 3, and then input to the control board 33a on the side of the main lock 2 via the control board 33b. .
Based on these signals, arithmetic processing is performed by software in the control board 33a on the main lock 2 side, and signals for operating the motors 72a and 72b are transmitted from the main lock 2 side.
That is, not only the motor 72a on the main lock 2 side but also the motor 72b on the sub lock 3 side is controlled by the control board 33a on the main lock 2 side.
Specifically, the control board 33a on the main lock 2 side has a built-in switching circuit 85 as shown in FIG. 13, and not only the motor 72a on the main lock 2 side but also the motor 72a on the sub lock 3 side, Starting, stopping, and reverse rotation are performed by the switching circuit 85 of the control board 33a.
Further, a transmission signal to the antenna 16 and a signal for lighting a lamp (not shown) are all transmitted from the control board 33a on the main lock 2 side.

Moreover, the electric lock 1 of the present embodiment includes a characteristic power supply system.
That is, as shown in FIGS. 11, 12, and 13, the power supply unit 35 a of the main lock 2 has four batteries 76 connected in series and generates a DC voltage of 6 volts. As for the power supply unit 35b of the secondary lock 3, four batteries 76 are connected in series to generate a DC voltage of 6 volts.
However, the power supply unit 35a of the main lock 2 and the power supply unit 35b of the sublock 3 are connected in parallel to serve as a power source for the battery 76 having a voltage of 6 volts and a capacity of two. This power is once input to the main lock 2 side. Electric power is supplied from the main lock 2 side to the secondary lock 3 side through power lines 86 and 87.

In the electric lock 1 of this embodiment, since the power supply units 35a and 35b are connected in parallel as described above, the capacity is large. Power supply lasts longer.
Further, since the power source is distributed to the main lock 2 and the sub-lock 3, the external shapes of the individual power supply portions 35a and 35b are small. Therefore, the size of the main lock 2 and the sub lock 3 itself is not excessively large, and the electric lock 1 of the present embodiment can be attached to a portion where the existing lock is attached.

Next, operation | movement of the electric lock 1 of this embodiment is demonstrated.
The electric lock of this embodiment can be unlocked and unlocked by both the key 90 (FIG. 2) and the card 83 (FIG. 11).
When using the card 83 to lock and unlock, the switch 15 provided in the detection box 21 is pressed and the card 83 is held over the detection box 21. A signal that the switch 15 is pressed is input to the control board 33a of the main lock 2 through a signal line, and power is supplied from the main lock 2 side to the antenna 16 to generate an electromagnetic wave.
The card 83 receives this electromagnetic wave, generates power, and transmits a predetermined radio wave. The radio wave transmitted from the card 83 is input to the control board 33a through the signal line and analyzed.
If the signal transmitted by the card 83 meets a predetermined condition, the switching circuit 85 of the control board 33a functions, and a switch for starting the motor 72a on the main lock 2 side and the motor 72b on the sub lock 3 side is activated. Turn on.

On the other hand, power is supplied to the switching circuit 85 of the control board 33a on the side of the main lock 2 from the power supply portions 35a and 35b of the two locks.
That is, the power supply units 35a and 35b of the two locks are connected in parallel to constitute a large-capacity power supply, and the power of the combined power supply is supplied to the contact of the switching circuit 85 of the control board 33a.
When the switching circuit 85 is connected, electric power is sequentially supplied to the motor 72a in the main lock 2 and the motor 72b in the sub lock 3. The power supply to the motor 72a in the main lock 2 and the motor 72b in the sub lock 3 is performed with a time difference.

  As a result, the dead bolt 43 appears and disappears from the main lock 2 and the sub-lock 3, and locking or unlocking is performed.

In the embodiment described above, the protruding portions 51 provided on the main lock 2 and the sub-lock 3 are provided on the lower side of the main body 50, but may be provided on the upper side of the main body 50.
Further, as shown in FIG. 14, protrusions 51 may be provided above and below the main body 50.

  In the above-described embodiment, the number of batteries stored in the main lock 2 and the sub-lock 3 is the same, but these may be different. For example, in the power supply unit of the main lock 2, three batteries are connected in parallel, and in the power supply unit of the sublock 3, two batteries are connected in parallel, and the two power supply units are connected in parallel. It may be a thing.

  Although the embodiment described above uses a motor as a power source, a solenoid may be used instead of the motor.

DESCRIPTION OF SYMBOLS 1 Electric lock 2 Main lock 3 Secondary lock 5 Door 7, 8 Hinge 12 Latch lock 15 Switch 16 Antenna 20 Cylinder 21 Detection box 22 Locking cavity 23 Insertion opening 30 Lock case 31 Lock mechanism 32 Power unit 33 Control board 35a, 35b Power supply part 36 Decorative plate 37 Mechanism accommodating part 38 Mounting flange part 40 Box body part 41 Front lid 43 Dead bolt 50 Body part 51 Projection part 60 Missing part 72a, 72b Motor 70 Hub 85 Switching circuit

Claims (5)

  A plurality of lock portions that have a power source and can be electrically opened and closed, and each of the plurality of lock portions is housed in an independent lock case, and each lock case has a power supply portion with a built-in battery. An electric lock characterized in that the power supply units are electrically connected in parallel.   The power source is a motor, and the switching circuit of the motor of the plurality of lock portions is housed in a specific lock case, and the motors housed in other lock cases are controlled by the switching circuit housed in the specific lock case. The electric lock according to claim 1. An electric lock in which a lock case is inserted from an insertion opening formed on an end surface of a door into a lock storage cavity formed inside the door,
The lock case has a main body part and a protruding part that protrudes upward or downward from the main body part on the basis of the mounting posture, and the total height of the lock case including the main body part and the protruding part is The electric lock according to claim 1 or 2, wherein the length of the opening for insertion is higher, and the height of the main body is lower than the length of the opening for insertion.   4. The electric lock according to claim 3, wherein the main body portion of the lock case is substantially square, and the protruding portion is also substantially square.   The electric lock according to claim 3 or 4, wherein the main body portion of the lock case has a shape in which a part of a square is missing.

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