JP6972707B2 - Cylinder lock - Google Patents

Description

The present invention relates to a cylinder lock using a dimple key.

Some cylinder locks are configured to be unlocked by a dimple key having a recess for unlocking (unlocking recess) formed on the surface of the key.
The rotor constituting this cylinder lock contains a tumbler that can be engaged with the unlocking recess of the dimple key.
For example, in the cylinder lock of Patent Document 1, when the dimple key is not inserted into the rotor, the pin-shaped tumbler housed in the rotor is pushed out from the peripheral surface of the rotor by the urging force of the spring, and the rotor case is used. Engage in and the rotor becomes non-rotatable. Further, when the dimple key is inserted into the rotor in the correct direction, the tumbler engages with the unlocking recess of the dimple key and retracts inward from the peripheral surface of the rotor, so that the rotor can rotate. On the other hand, when the dimple key is inserted into the rotor in a different direction, the tumbler is pushed out of the rotor and engages with the rotor case, so that the rotor cannot rotate.

By the way, since the cylinder lock of Patent Document 1 uses a pin-shaped tumbler formed by cutting, there is a problem in terms of manufacturing cost.
There is a cylinder lock that uses a plate-shaped tumbler instead of a pin-shaped tumbler (for example, Patent Document 2).
For the cylinder lock of Patent Document 2, by using a plate-shaped tumbler formed into a predetermined shape by press working, the manufacturing cost can be suppressed as compared with a pin-shaped tumbler formed by cutting.

Japanese Unexamined Patent Publication No. 2016-44438 Japanese Unexamined Patent Publication No. 2003-213991

By the way, the plate-shaped tumbler of Patent Document 2 is housed in the rotor facing a direction orthogonal to the insertion direction of the dimple key. This plate-shaped tumbler has a complicated shape in which a passage hole through which the dimple key passes is formed in the center of the plate, and an unlocking convex portion that engages with the unlocking recess of the dimple key is formed on the inner surface of the passage hole. , The manufacturing cost does not decrease so much.
Further, since the plate-shaped tumbler of Patent Document 2 is composed of a plate material having a two-divided shape, the number of parts is large and it takes time and effort to assemble.
Therefore, an object of the present invention is to provide a cylinder lock capable of reducing the manufacturing cost by using a plate tumbler having a simple shape and reducing the number of parts of the plate tumbler.

In order to achieve the above object, the cylinder lock according to one aspect of the present invention includes a rotor, a key insertion hole opened in a rectangular shape along the axis of the rotor, and a rotor case for rotatably storing the rotor. A dimple key that has multiple unlocking recesses formed in the length direction of the key cord surface and is inserted into the key insertion hole, and a dimple key that is stored in the rotor and moved to the key insertion hole side to unlock the recess or the key code. A tumbler having an unlocking convex portion or an unlocking flat portion that engages with the surface is stored in the rotor, crosses the tumbler, and moves to the key insertion hole side to engage with the rotor case. Equipped with a side bar that can be released and the rotor can be rotated, the tumbler is stored in the rotor so that the plate length direction is along the axis, and multiple unlocking protrusions are placed on the plate end on the key insertion hole side. The dimple key is a plate-shaped tumbler in which the part or the unlocking flat part is formed along the plate length direction , and the dimple key is a reversible specification in which a plurality of unlocking recesses are formed on the front surface and the back surface of the key cord surface. Two sets of the plate-shaped tumblers are housed so as to face each other from a short direction orthogonal to the longitudinal direction of the key insertion hole extending in a rectangular shape and extending along the axis of the rotor. ..

The cylinder lock according to the present invention can reduce the manufacturing cost and the number of parts of the plate tumbler by using a plate tumbler having a simple shape.

It is a perspective view which shows the cylinder lock of 1st Embodiment which concerns on this invention. It is an exploded perspective view which shows the cylinder lock of 1st Embodiment which concerns on this invention. It is a figure which showed the 1st Embodiment which concerns on this invention from the dimple key side. It is sectional drawing which follows the 2nd axis orthogonal direction X2 of FIG. It is sectional drawing which follows the 1st axis orthogonal direction X1 of FIG. FIG. 5 is a view taken along the line AA of FIG. It is a figure which shows the 1st surface (FIG. 7 (a)), 2nd surface (FIG. 7 (b)) of a dimple key. It is a perspective view which shows the cylinder lock of the 2nd Embodiment which concerns on this invention. It is sectional drawing which follows the 2nd axis orthogonal direction X2 of the 2nd Embodiment which concerns on this invention. 9 is a view taken along the line BB in FIG. 9.

Next, the first and second embodiments of the present invention will be described with reference to the drawings. In the description of the drawings below, the same or similar parts are designated by the same or similar reference numerals. However, it should be noted that the drawings are schematic, and the relationship between the thickness and the plane dimensions, the ratio of the thickness of each layer, etc. are different from the actual ones. Therefore, the specific thickness and dimensions should be determined in consideration of the following explanation. In addition, it goes without saying that parts having different dimensional relationships and ratios are included between the drawings.

Further, the first and second embodiments shown below exemplify devices and methods for embodying the technical idea of the present invention, and the technical idea of the present invention is the material of the component parts. , Shape, structure, arrangement, etc. are not specified to the following. The technical idea of the present invention may be modified in various ways within the technical scope specified by the claims described in the claims.
Hereinafter, embodiments for carrying out the present invention (hereinafter referred to as embodiments) will be described in detail with reference to the drawings. The terms such as "top", "bottom", "bottom", "front", and "rear" described in the following description are used with reference to the directions in the attached drawings.

[Cylinder lock of the first embodiment]
FIG. 1 shows a cylinder lock 1 of the first embodiment of the reversible specification.
The cylinder lock 1 includes a cylinder body 2 and a dimple key 3, and a unit connection portion 4 connected to a contact unit (not shown) is connected to the cylinder body 2.
The cylinder body 2 includes a rotor case 5 and a rotor 6 rotatably housed in the rotor case 5.

The rotor case 5 is a hollow cylindrical member, and as shown in FIG. 2, the engaging protrusions 18a and 19a of the first sidebar 18 and the second sidebar 19, which will be described later, can be inserted into the inner peripheral surface thereof. The first to fourth engaging grooves 5a to 5d are formed.
As shown in FIG. 2, the rotor 6 is a cylindrical member, and a key insertion hole 7 having a rectangular shape is formed on one end surface 6a of the rotor 6 in the axial direction (axis P1 direction) (the rotor 6 is formed in a rectangular shape (axis P1 direction). See Figure 3). The key insertion hole 7 is formed so as to extend in the axis P1 direction for inserting the dimple key 3.

Here, as shown in FIG. 2, the direction orthogonal to the axis P1 direction and extending in the width direction of the key insertion hole 7 is referred to as the first axis orthogonal direction X1, and the key is orthogonal to the first axis orthogonal direction X1. The direction extending in the elongated direction of the insertion hole is referred to as the second axis orthogonal direction X2.
As shown in FIG. 2, the rotor 6 includes the first to fourth plate tumblers 10 to 13, four compression springs for tumblers 15, four spring holding members 16, and the first sidebar 18 described above. The second sidebar 19 and the two sidebar compression springs 20 are housed and mounted inside the rotor case 5.
Here, in the rotor case 5 in which the rotor 6 in which the above members are housed is mounted, the second engaging groove 5b formed on the inner peripheral surface thereof is arranged along the second axis orthogonal direction X2. ..

As shown in FIGS. 2 and 5, on one outer peripheral side of the rotor 6 in the orthogonal direction X1 of the first axis, a first tumbler storage chamber 21 and a second tumbler storage chamber 22 communicating with the key insertion hole 7 are shafts P1. It is formed along the direction. Further, as shown in FIG. 5, on the other outer peripheral side of the rotor 6 in the orthogonal direction X1 of the first axis, the third tumbler storage chamber 23 and the fourth tumbler storage chamber 24 communicating with the key insertion hole 7 are located in the axis P1 direction. It is formed along.
As shown in FIGS. 2 and 4, on one outer peripheral side of the rotor 6 in the orthogonal direction X2 of the second axis, the first sidebar storage chamber 26 communicating with the first tumbler storage chamber 21 and the third tumbler storage chamber 23 A second sidebar storage chamber 27 communicating with the second tumbler storage chamber 22 and the fourth tumbler storage chamber 24 is formed along the axis P1 direction.

The first sidebar 18 is stored in the first sidebar storage chamber 26, and the second sidebar 19 is stored in the second sidebar storage chamber 27.
As shown in FIG. 2, the first sidebar 18 is a U-shaped member including a pair of legs 18b, 18c and a connecting portion 18d connecting the upper ends of the pair of legs 18b, 18c. The above-mentioned engaging ridge 18a is formed on the outside of the connecting portion 18d.
As shown in FIG. 6, the first sidebar storage chamber 26 is a pair of a concave spring receiving portion 26a and a pair of communication with the first and third tumbler storage chambers 21 and 23 at positions sandwiching the spring receiving portion 26a. The leg passage holes 26b and 26c are formed. The first sidebar 18 has a pair of leg portions 18b and 18c in a pair of leg passage holes 26b in a state where the inner surface of the connecting portion 18d is in contact with the sidebar compression spring 20 mounted on the spring receiving portion 26a. , 26c.

As shown in FIG. 2, the second sidebar 19 also has a U-shape having a pair of leg portions 19b and 19c and a connecting portion 19d connecting the pair of leg portions 19b and 19c. The above-mentioned engaging ridge 19a is formed on the outside of 19d.
The second sidebar storage chamber 27 also has the same shape as the first sidebar storage chamber 26. The second sidebar 19 brings the inner surface of the connecting portion 19d into contact with the sidebar compression spring 20 mounted on the spring receiving portion (not shown) of the second sidebar storage chamber 27. Then, the pair of legs 19b and 19c are inserted into the pair of leg passage holes (not shown) communicating with the second and fourth tumbler storage chambers 22 and 24 of the second sidebar storage chamber 27.

FIG. 7A shows the first surface 3a of the reversible dimple key 3, and FIG. 7B shows the second surface 3b of the dimple key 3 which is the back surface of the first surface 3a. A plurality of large-diameter recesses 40 and a plurality of small-diameter recesses 41 are formed on the first surface 3a and the second surface 3b, respectively. The depth of the small-diameter recess 41 is formed to be approximately half the depth of the large-diameter recess 40.
The dimple key 3 has a key code composed of three combinations of a large-diameter recess 40, a small-diameter recess 41, and a flat surface portion 42 in which the recess is not formed.
On the first surface 3a and the second surface 3b of the dimple key 3, the large-diameter recess 40 and the small-diameter recess 41 are on the first straight line L1 and the second straight line L2 whose centers extend in the length direction of the dimple key 3. It is formed so as to be located on one side. The first straight line L1 is located on the upper side of the first surface 3a and the second surface 3b, and the second straight line L2 is located on the lower side of the first surface 3a and the second surface 3b.

Four large-diameter recesses 40 are formed on the first straight line L1 of the first surface 3a, and on the second straight line L2, the length is the second large-diameter recess 40 from the tip on the first straight line L1. The small-diameter recess 41 is formed at the same position in the direction, and the small-diameter recess 41 is formed at the same position in the length direction as the fourth large-diameter recess 40 from the tip on the first straight line L1.
On the upper side of the second surface 3b corresponding to the first straight line L1 of the first surface 3a, two small-diameter recesses 41 formed on the second straight line L2 of the first surface 3a are located at the same position in the length direction. Small diameter recess 41 is formed. Further, on the lower side of the second surface 3b corresponding to the second straight line L2 of the first surface 3a, it is the same as the four large-diameter recesses 40 formed on the first straight line L1 of the first surface 3a in the length direction. Four large-diameter recesses 40 are formed at the positions.
As described above, when the dimple key 3 of the first embodiment is rotated by 180 ° around the central axis and inserted into the key insertion hole 7, the large-diameter recess 40 has the same arrangement in the first straight line L1 and the second straight line L2. It is formed as a reversible dimple key in which the small diameter recess 41 is located.

As shown in FIG. 5, in the first plate tumbler 10 housed in the first tumbler storage chamber 21, the first small-diameter convex portion 45 is formed so as to protrude from the inner end surface protruding from the key insertion hole 7. The first flat portion 46 is formed at a position separated from the first small-diameter convex portion 45 in the axis P1 direction.
Further, a concave spring receiving portion 47 is formed on the outer end surface of the first plate tumbler 10, and by cutting out both side portions of the first plate tumbler 10 in the axis P1 direction, the first sidebar 18 is formed. Leg insertion recesses 48, 48 into which the tip of the leg 18b can be inserted are formed.

The second plate tumbler 11 housed in the second tumbler storage chamber 22 has a second small-diameter convex portion 50 protruding from the inner end surface protruding from the key insertion hole 7, and the second small-diameter convex portion 50 is formed. The second flat portion 51 is formed at a position separated from the axis P1 in the direction of the axis P1.
The third plate tumbler 12 housed in the third tumbler storage chamber 23 has a first large-diameter convex portion 52 protruding from the inner end surface protruding from the key insertion hole 7, and has a first large-diameter convex portion. A second large-diameter convex portion 53 is formed at a position separated from the portion 52 in the axis P1 direction.
The fourth plate tumbler 13 housed in the fourth tumbler storage chamber 24 has a third large-diameter convex portion 54 protruding from the inner end surface protruding from the key insertion hole 7, and has a first large-diameter convex portion. A fourth large-diameter convex portion 55 is formed at a position separated from the portion 52 in the axis P1 direction.

The second to fourth plate tumblers 11 to 13 have the same structure as the first plate tumbler 10, and a concave spring receiving portion 47 is formed on the outer end surface.
Further, by cutting out both side portions of the second plate tumbler 11 in the axis P1 direction, leg insertion recesses 48 and 48 into which the tips of the legs 19b of the second sidebar 19 can be inserted are formed. Further, by notching both side portions of the third plate tumbler 12 in the axis P1 direction, leg insertion recesses 48 and 48 into which the tips of the legs 18c of the first sidebar 18 can be inserted are formed.
Further, by notching both side portions of the fourth plate tumbler 13 in the axis P1 direction, leg insertion recesses 48 and 48 into which the tips of the legs 19c of the second sidebar 19 can be inserted are formed.
The first to fourth plate tumblers 10 to 13 housed in the first to fourth tumbler storage chambers 21 to 24 have a spring holding member at the other end of the tumbler compression spring 15 having one end mounted on the spring receiving portion 47. It is mounted inside the rotor case 5 in a state where the 16 is received.

Here, the shaft described in the present invention corresponds to the shaft P1 of the rotor 6, the key code surface described in the present invention corresponds to the first surface 3a and the second surface 3b, and the unlocking recess described in the present invention is. Corresponding to the large-diameter concave portion 40 and the small-diameter concave portion 41, the unlocking convex portion described in the present invention corresponds to the first small-diameter convex portion 45, the second small-diameter convex portion 50, and the first to fourth large-diameter convex portions 52 to 55. However, the unlocked flat portion described in the present invention corresponds to the first flat portion 46 and the second flat portion 51, and the plate-shaped tumbler described in the present invention corresponds to the first to fourth plate tumblers 10 to 13. The front surface and the back surface of the key cord surface described in the present invention correspond to the first surface 3a and the second surface 3b, and the spring member described in the present invention corresponds to the compression spring 15 for a tumbler, and the spring holding described in the present invention. The member corresponds to the spring holding member 16, the engaging recess described in the present invention corresponds to the second engaging groove 5b, and the engaging convex portion described in the present invention corresponds to the engaging protrusions 18a and 19a. The passing portion described in the present invention corresponds to the leg insertion recess 48, and the passing portion described in the present invention corresponds to the legs 18b, 18c, 19b, 19c.

[Operation of the cylinder lock of the first embodiment]
Next, the operation of the cylinder lock 1 of the first embodiment having the above configuration will be described.
As shown in FIG. 5, when the dimple key 3 is inserted into the key insertion hole 7 of the cylinder body 2, the first straight line L1 (see FIG. 7) of the dimple key 3 coincides with the first axis orthogonal direction X1 of the rotor 6.
As shown in FIG. 5, the first small-diameter convex portion 45 of the first plate tumbler 10 pushed by the spring force of the tumbler compression spring 15 enters the small-diameter concave portion 41 on the right side of the first surface 3a of the dimple key 3. The first flat portion 46 of the one-plate tumbler 10 abuts on the flat portion 42 of the first surface 3a. Further, the second small-diameter convex portion 50 of the second plate tumbler 11 pushed by the spring force of the compression spring 15 for the tumbler enters the small-diameter concave portion 41 on the left side of the first surface 3a of the dimple key 3, and the second plate tumbler 11 The second flat portion 51 abuts on the flat portion 42 of the first surface 3a.

Further, the first large-diameter convex portion 52 and the second large-diameter convex portion 53 of the third plate tumbler 12 pushed by the spring force of the compression spring 15 for the tumbler, and the third large-diameter convex portion 54 of the fourth plate tumbler 13. The fourth large-diameter convex portion 55 and the fourth large-diameter convex portion 55 enter into the four large-diameter concave portions 40 on the second surface 3b of the dimple key 3.
Then, as shown in FIG. 5, inside the large-diameter concave portion 40 and the small-diameter concave portion 41 of the dimple key 3, the first small-diameter convex portion 45, the second small-diameter convex portion 50, and the first to fourth large-diameter convex portions 53 to When the 55 is inserted, the first to fourth plate tumblers 10 to 13 move to the key insertion hole 7 side. As a result, as shown in FIG. 6, the legs 18b and 18c of the first sidebar 18 face the leg insertion recesses 48 of the first plate tumbler 10 and the third plate tumbler 12. Although not shown, the legs 19b and 19c of the second sidebar 19 face the leg insertion recesses 48 of the second plate tumbler 11 and the fourth plate tumbler 13.

When the dimple key 3 is inserted into the key insertion hole 7, as shown in FIG. 6, the engaging protrusions 18a of the first sidebar 18 and the second sidebar 19 are inserted into the second engaging groove 5b of the rotor case 5. , 19a is included.
When the dimple key 3 is turned in this state, the legs 18b, 18c and the legs 19b, 19c of the first sidebar 18 and the second sidebar 19 are inserted into the leg insertion recesses 48 of the first to fourth plate tumblers 10 to 13. And the engaging protrusions 18a and 19a come out from the second engaging groove 5b, so that the rotor 6 can rotate with respect to the rotor case 5, and the cylinder lock 1 can be unlocked.

Further, since the cylinder lock 1 of the first embodiment has a reversible specification, when the dimple key 3 is reversedly inserted into the key insertion hole 7 of the cylinder body 2, the dimple key 3 is inserted in the first axis orthogonal direction X1 of the rotor 6. The second straight line L2 (see FIG. 7) of No. 3 coincides with each other, and the state shown in FIGS. 5 and 6 is obtained. As a result, when the dimple key 3 is turned, the legs 18b, 18c and the legs 19b, 19c of the first sidebar 18 and the second sidebar 19 are inserted into the leg insertion recesses 48 of the first to fourth plate tumblers 10 to 13. And the engaging protrusions 18a and 19a come out from the second engaging groove 5b, so that the rotor 6 can rotate with respect to the rotor case 5.

On the other hand, when the dimple key 3 is not inserted into the key insertion hole 7 or when a key different from the dimple key 3 is inserted, the leg insertion recess 48 of the first plate tumbler 10 and the third plate tumbler 12 is inserted. The legs 18b and 18c of the first sidebar 18 do not face each other, and the legs 19b and 19c of the second sidebar 19 also face the leg insertion recesses 48 of the second plate tumbler 11 and the fourth plate tumbler 13. do not. As a result, the state in which the engaging protrusions 18a and 19a of the first sidebar 18 and the second sidebar 19 are engaged with the second engaging groove 5b of the rotor case 5 is maintained, so that the rotor 6 is the rotor case 5. It becomes impossible to rotate with respect to.

[Effect of the cylinder lock of the first embodiment]
Next, the effect of the cylinder lock 1 of the first embodiment will be described.
When a conventional pin-shaped tumbler is used, two small-diameter recesses 41 on the first surface 3a of the dimple key 3, a first flat portion 46, a second flat portion 51, and four large-diameter recesses 40 on the second surface 3b are used. Eight pin-shaped tumblers corresponding to the above are required. In addition, the same number of spring members that give spring force to each pin-shaped tumbler are required.
On the other hand, since the first embodiment is composed of four plate tumblers (first plate tumbler 10 to fourth plate tumbler 13), the number of parts can be reduced and the compression spring for the tumbler can be reduced. The number of parts of the 15 and the spring holding member 16 can also be reduced.

Further, the first to fourth plate tumblers 10 to 13 do not form a passage hole or the like for the dimple key 3, and the first small diameter convex portion 45, the first flat portion 46, and the inside located on the key insertion hole 7 side. It is a simple shape in which the second flat portion 51 and the first large-diameter convex portion 52 to the fourth large-diameter convex portion 55 are formed. Therefore, it is possible to reduce the manufacturing cost of the first plate tumbler 10 to the fourth plate tumbler 13.
Further, in the structure for unlocking the cylinder lock 1, the legs 18b, 18c, 19b, 19c of the first sidebar 18 and the second sidebar 19 are the leg insertion recesses 48 of the first to fourth plate tumblers 10 to 13. It is a structure that gets in. That is, when the legs 18b, 18c, 19b, 19c enter the leg insertion recess 48, the first sidebar 18 and the second sidebar 19 move to the key insertion hole 7 side. Then, the engaging protrusions 18a and 19a of the first sidebar 18 and the second sidebar 19 come out from the second engaging groove 5b of the rotor case 5, so that the rotor 6 can rotate with respect to the rotor case 5. It can be unlocked by rotating the dimple key 3.
Therefore, the edges of the first to fourth plate tumblers 10 to 13 are cut out to form the leg insertion recess 48, and the legs 18b, 18c, 19b, 19c of the first sidebar 18 and the second sidebar 19 are formed. The cylinder lock 1 can be formed with a simple structure that allows engagement.

[Cylinder lock of the second embodiment]
Next, FIGS. 8 to 10 show the cylinder lock 60 of the second embodiment.
The cylinder lock 60 of the second embodiment is also a reversible specification, and the same components as those of the cylinder lock 1 of the first embodiment are designated by the same reference numerals and the description thereof will be omitted.
As shown in FIG. 8, the rotor 61 constituting the cylinder lock 60 of the second embodiment is a cylindrical member, and a key insertion having a rectangular opening in one end surface 61a in the axial direction (axis P1 direction). The hole 7 is formed.

As shown in FIGS. 8 and 9, a fifth tumbler storage chamber 62 communicating with the key insertion hole 7 is formed along the axis P1 direction on one outer peripheral side of the rotor 61 in the first axis orthogonal direction X1. There is. Further, a sixth tumbler storage chamber 63 communicating with the key insertion hole 7 is formed along the axis P1 direction on the other outer peripheral side of the rotor 61 in the first axis orthogonal direction X1.
As shown in FIGS. 8 and 10, on one outer peripheral side of the rotor 61 in the orthogonal direction X2 of the second axis, a third sidebar storage chamber 64 communicating with the fifth tumbler storage chamber 62 and the sixth tumbler storage chamber 63 Is formed along the axis P1 direction.

The third sidebar 65 is stored in the third sidebar storage chamber 64.
As shown in FIG. 10, the third sidebar storage chamber 64 is a pair of concave spring receiving portions 64a and a pair of communication with the fifth and sixth tumbler storage chambers 62 and 63 at positions sandwiching the spring receiving portions 64a. Leg passage holes 64b and 64c are formed.
As shown in FIG. 8, the third sidebar 65 projects from the connecting portion 65d connecting the pair of legs 65b, 65c and the upper ends of the pair of legs 65b, 65c, and the connecting portion 65d. The engaging ridges 65a and the like are provided.
In the third sidebar 65, the pair of legs 65b and 65c are in contact with the pair of leg passage holes 64b in a state where the inner surface of the connecting portion 65d is in contact with the sidebar compression spring 20 mounted on the spring receiving portion 64a. It is inserted in 64c.

As shown in FIG. 9, the fifth plate tumbler 66 is stored in the fifth tumbler storage chamber 62, and the sixth plate tumbler 69 is stored in the sixth tumbler storage chamber 63.
The fifth plate tumbler 66 has a first small diameter convex portion 45, a first flat portion 46, a second small diameter convex portion 50, and a second flat portion 51 separated in the P1 direction from the inner end surface protruding from the key insertion hole 7. All of is formed.
A concave spring receiving portion 67 is formed on the outer end surface of the fifth plate tumbler 66, and the legs of the third sidebar 65 are formed by cutting out both side portions of the fifth plate tumbler 66 in the axis P1 direction. Leg insertion recesses 68 and 68 into which the tip of the portion 65b can be inserted are formed.

In the sixth plate tumbler 69, all of the first to fourth large-diameter convex portions 53 to 55 are formed on the inner end surface protruding from the key insertion hole 7 so as to be separated in the P1 direction.
A concave spring receiving portion 67 is formed on the outer end surface of the sixth plate tumbler 69, and the legs of the third sidebar 65 are formed by cutting out both side portions of the sixth plate tumbler 69 in the axis P1 direction. Leg insertion recesses 68 and 68 into which the tip of the portion 65c can be inserted are formed.
The fifth to sixth plate tumblers 66 and 69 housed in the fifth to sixth tumbler storage chambers 62 and 63 have a spring holding member at the other end of the tumbler compression spring 15 having one end mounted on the spring receiving portion 67. It is mounted inside the rotor case 5 in a state where the 16 is received.
Here, the plate-shaped tumbler described in the present invention corresponds to the fifth and sixth plate tumblers 66, 69, and the engaging convex portion described in the present invention corresponds to the engaging ridge 65a, which is described in the present invention. The passed portion corresponds to the leg insertion recess 68, and the passing portion described in the present invention corresponds to the legs 65b and 65c.

[Operation of the cylinder lock of the second embodiment]
Next, the operation of the cylinder lock 60 of the second embodiment having the above configuration will be described.
As shown in FIG. 9, when the dimple key 3 is inserted into the key insertion hole 7 of the rotor 61, the first straight line L1 of the dimple key 3 coincides with the first axis orthogonal direction X1 of the rotor 61.
As shown in FIG. 9, the first small-diameter convex portion 45 of the fifth plate tumbler 66 pushed by the spring force of the tumbler compression spring 15 enters the small-diameter concave portion 41 on the right side of the first surface 3a of the dimple key 3. 1 The flat portion 46 abuts on the flat portion 42 of the first surface 3a, the second small diameter convex portion 50 enters the small diameter concave portion 41 on the left side of the first surface 3a of the dimple key 3, and the second flat portion 51 is the first surface. It abuts on the flat surface portion 42 of 3a.

Further, the first large-diameter convex portion 52, the second large-diameter convex portion 53, the third large-diameter convex portion 54, and the fourth large-diameter convex portion of the sixth plate tumbler 69 pushed by the spring force of the compression spring 15 for the tumbler. 55 enters the four large-diameter recesses 40 on the second surface 3b of the dimple key 3.
Then, the first small-diameter convex portion 45, the second small-diameter convex portion 50, and the first to fourth large-diameter convex portions 53 to 55 enter the inside of the large-diameter concave portion 40 and the small-diameter concave portion 41 of the dimple key 3. 5, 6th plate tumblers 66, 69 move to the key insertion hole 7 side. As a result, as shown in FIG. 10, the legs 65b and 65c of the third sidebar 65 face the leg insertion recesses 68 of the fifth plate tumbler 66 and the sixth plate tumbler 69.

Then, when the dimple key 3 is inserted into the key insertion hole 7, as shown in FIG. 10, the engaging protrusion 65a of the third sidebar 65 is inserted into the second engaging groove 5b of the rotor case 5. ..
When the dimple key 3 is turned in this state, the legs 65b and 65c of the third sidebar 65 enter into the leg insertion recesses 68 of the fifth and sixth plate tumblers 66 and 69, and are engaged from the second engaging groove 5b. The rotor 61 becomes rotatable with respect to the rotor case 5 by the protrusion 65a.
Since the cylinder lock 1 of the second embodiment is also reversible, when the dimple key 3 is reversedly inserted into the key insertion hole 7 of the rotor 61, the dimple key 3 is inserted in the first axis orthogonal direction X1 of the rotor 61. The two straight lines L2 coincide with each other, and as shown in FIGS. 9 and 10, the engaging protrusions 18a and 19a come out from the second engaging groove 5b, so that the rotor 61 becomes rotatable with respect to the rotor case 5. The cylinder lock 60 can be unlocked.

On the other hand, when the dimple key 3 is not inserted into the key insertion hole 7 or when a key different from the dimple key 3 is inserted, the leg insertion recess 68 of the fifth plate tumbler 66 and the sixth plate tumbler 69 is inserted. The legs 65b and 65c of the third sidebar 65 do not face each other. As a result, the rotor 61 is held in a state where the engaging protrusion 65a of the third sidebar 65 is engaged with the second engaging groove 5b of the rotor case 5, so that the rotor 61 cannot rotate with respect to the rotor case 5. Become.

[Effect of the cylinder lock of the second embodiment]
Next, the effect of the cylinder lock 60 of the second embodiment will be described.
The cylinder lock 60 of the second embodiment has two small-diameter recesses 41 on the first surface 3a of the dimple key 3, a first flat portion 46, a second flat portion 51, and four large-diameter recesses on the second surface 3b. Since only two fifth and sixth plate tumblers 66 and 69 corresponding to 40 are used, the number of parts can be further reduced as compared with the first embodiment, and the tumbler compression spring 15 and the spring holding member 16 can be used. The number of parts can also be reduced.
Further, since the fifth and sixth plate tumblers 66 and 69 have a simple shape, the manufacturing cost can be reduced.

In the first and second embodiments, a reversible cylinder lock is used, and either the large-diameter recess 40 or the small-diameter recess 41 is formed on the first surface 3a and the second surface 3b of the dimple key 3, according to the present invention. The gist is not limited to this, and a non-reversible cylinder lock in which either the large-diameter recess 40 or the small-diameter recess 41 is formed only on the first surface 3a of the dimple key 3 may be used. In the case of the non-reversible specification, the tumbler storage chamber communicating with the key insertion hole 7 of the rotor 6 (61) may be formed only on one end side in the orthogonal direction of the first axis, reducing the number of parts of the plate tumbler. At the same time, the number of parts of the tumbler compression spring 15 and the spring holding member 16 can be reduced.

1 Cylinder lock 2 Cylinder body 3 Dimple key 3a 1st surface 3b 2nd surface 4 Unit connection 5 Rotor case 5a to 5d 1st to 4th engagement groove 6 Rotor 6a One end surface 7 Key insertion hole 10 to 13 1st ~ 4th plate tumbler 15 tumbler compression spring 16 spring holding member 18 1st sidebar 18a, 19a engaging ridges 18b, 18c, 19b, 19c legs 18d, 19d connecting part 19 2nd sidebar 20 compression for sidebar Spring 21 1st tumbler storage room 22 2nd tumbler storage room 23 3rd tumbler storage room 24 4th tumbler storage room 26 1st sidebar storage room 26a Spring receiving parts 26b, 26c Leg passage hole 27 2nd sidebar storage room 40 Large-diameter concave portion 41 Small-diameter concave portion 42 Flat surface portion 45 First small-diameter convex portion 46 First flat portion 47 Spring receiving portion 48 Leg insertion recess 50 Second small-diameter convex portion 51 Second flat portion 52 First large-diameter convex portion 53 2 Large-diameter convex portion 54 3rd large-diameter convex portion 55 4th large-diameter convex portion 60 Cylinder lock 61 Rotor 61a One end surface 62 5th tumbler storage chamber 63 6th tumbler storage chamber 64 3rd sidebar storage chamber 65 3rd side Bar 65a Engagement ridge 65b, 65c Leg 65d Connecting part 64a Spring receiving part 64b, 64c Leg passing hole 66 5th plate tumbler 67 Spring receiving part 68 Leg insertion recess 69 6th plate tumbler L1 1st straight line L2 1st 2 Straight line P1 Axial direction of rotor X1 1st axis orthogonal direction X2 2nd axis orthogonal direction

Claims (4)

With the rotor
A key insertion hole that opens in a rectangular shape along the axis of the rotor,
A rotor case that rotatably stores the rotor and
A dimple key in which a plurality of unlocking recesses are formed in the length direction of the key cord surface and is inserted into the key insertion hole,
A tumbler housed in the rotor and formed with an unlocking recess, an unlocking convex portion engaged with the key cord surface, or an unlocking flat portion by moving to the key insertion hole side.
It is provided with a sidebar that is housed in the rotor and crosses the tumbler and moves to the key insertion hole side to disengage the rotor case and allow the rotor to rotate.
The tumbler is housed in the rotor so that the plate length direction is along the axis, and a plurality of the unlocking convex portions or the unlocking flat portions are plate lengths at the plate end portion on the key insertion hole side. It is a plate-shaped tumbler formed along the direction .
The dimple key is a reversible specification in which the plurality of unlocking recesses are formed on the front surface and the back surface of the key code surface.
Two sets of the plate-shaped tumblers are housed so as to face each other from a short direction orthogonal to the longitudinal direction of the key insertion hole extending in a rectangular shape and extending along the axis of the rotor. Cylinder lock. The plate-shaped tumbler is a single plate-shaped tumbler in which all of the plurality of unlocking protrusions engaged with the plurality of unlocking recesses formed on the key code surface are formed on the plate end portion. The cylinder lock according to claim 1. A spring member that applies a spring force that presses the plate-shaped tumbler toward the key insertion hole, and
The cylinder lock according to claim 1 or 2, further comprising a spring holding member that holds the spring member inside the rotor. The sidebar
It is provided with an engaging convex portion that enters the engaging concave portion formed on the inner peripheral surface of the rotor case and a passing portion that can pass through the passing portion formed on the plate-shaped tumbler.
When the sidebar moves to the key insertion hole side and the passing portion passes through the passed portion, the engaging convex portion comes out of the engaging concave portion and the rotor case and the sidebar are engaged. The cylinder lock according to any one of claims 1 to 3, wherein the cylinder lock is released.

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