RU2475614C2 - Mortise lock with cogged element of dead bolt unlocking - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: mortise lock comprises a body and a dead bolt and stop pins capable of entering the body and exiting it accordingly into an open and locked positions by means of a wheel pushing the bolt out. The wheel that pushes the bolt out is in a cogged connection with a gear, which has two pins protruding from one of its surfaces. Gear pins engage with a cogged rack connected with the dead bolt, and as the gear rotates, pins alternately enter grooves and exit grooves of the cogged rack and thus impart rectilinear motion to the cogged rack, and make the dead bolt enter the body and exit it. The gear engages with another gear, which also has two pins protruding from one of its surfaces. Gear pints engage with the first cogged rack and the second cogged rack, accordingly, which are attached to stop pins of the lock, and as the gear rotates, pints alternately enter the grooves and exit the grooves of the first and second cogged racks and make stop pins enter the body and exit from it.

EFFECT: expansion of an arsenal of technical means for designs of mortise locks.

8 cl, 15 dwg

Description

FIELD OF THE INVENTION

The present invention relates generally to a mortise lock assembly, and more particularly, to a mortise lock with an unlocking element of the locking bolt.

BACKGROUND OF THE INVENTION

Mortise lock is a castle of one of the most common types. The mortise lock is installed in the recess on the side of the door, namely, on the side that is adjacent to the adjacent surface of the door jamb when the door is closed. Due to the fact that the main body of the lock, containing most of its working elements, is located inside the door itself, access to these working elements is complicated for an attacker and thereby unauthorized access to a closed room or room is complicated.

Many conventional lock assemblies have a handle that opens the latch, overcoming the resistance of the return spring. Some mortise locks have locking bolts that are pushed out by turning the cylinder with a key, which can also control the latch. Some mortise locks have an auxiliary cylinder lock for actuating the auxiliary locking bolt.

Summary of the invention

The present invention is based on the task of creating an improved mortise lock assembly, which is further described in detail below.

Thus, in one embodiment of the present invention, there is provided a mortise lock having a housing, a latch and a locking bolt, which is capable of moving into the locked and unlocked positions, respectively, by means of a wheel pushing bolt inside the housing and outside of the housing, and an locking bolt unlocking element serving for selectively blocking and unlocking the movement of the locking bolt inside the housing to the unlocked position and having an element locking the bolt that blocks the movement of the locking bolt about the bolt, in this case, after the start of rotation of the ejector wheel bolt, the lever, which is in gear connection with the ejector wheel, pushes the unlocking element of the locking bolt from the blocking position of the locking bolt, and in the case of further rotation of the pushing wheel bolt moves the locking bolt inside the housing to the unlocked position .

In one non-limiting embodiment of the present invention, the locking bolt unlocking element has a plate, and the locking bolt element has protrusions extending inward from the plate which block the movement of the locking bolt, and the plate is slidable in the housing. The lever abuts against the hole in the plate and rotates with the gear located in the gear connection with the ejector wheel. The pusher wheel is in gear connection with two spur gears, which mesh with a gear that mesh with the gear that rotates with the lever.

In one non-limiting embodiment of the present invention, the ejector bolt is gear-engaged with the locking bolt by a coupling mechanism that engages the gear and by a pinion gear that rotates with the coupling mechanism only after the coupling mechanism has rotated at a predetermined distance along the arc and engages with a gear rack attached to the locking bolt, while after the start of rotation of the ejection When the bolt of the wheel is locked, the lever is pressed against the hole and pushes the unlocking element of the locking bolt out of the blocking position of the locking bolt, and in case of further rotation of the pushing bolt of the wheel, it rotates the gear wheel, the connecting mechanism and the pinion gear, which moves the gear rail so that the locking bolt moves inside cases in the unlocked position. The pusher wheel can be in gear connection with a gear rack attached to the lower locking pin, which enters the housing and exits the housing.

A gear rack can also engage with a gear, which in turn is in gear connection with another gear rack attached to an upper locking pin that enters the housing and exits the housing.

In one non-limiting embodiment of the present invention, the latch bolt has a protrusion that abuts against the latch pin pusher that can be moved by the ejector wheel latch, while the upper part of the latch pin pusher serves to make the latch pin shoulder move the latch. The latch pin pusher has an eye that is pushed by the cam portion of the ejector wheel bolt, while the upper part of the latch pin pusher abuts against a lever that pivots about the pivot axis and pushes the latch pin shoulder that pivots and moves the latch.

Brief Description of the Drawings

In order to provide a more complete understanding and appreciation of the present invention, a detailed description thereof follows with reference to the drawings, in which:

figure 1 shows a simplified side view illustrating the internal components of the mortise lock in the locked position, which is designed and operates according to one of the embodiments of the present invention,

on figa shows a simplified enlarged view of the mortise lock illustrated in figure 1, which is designed and operates according to one embodiment of the present invention, from the side of the latch pusher and the cam of the cylinder,

on figb shows a simplified enlarged sectional view of the locking bolt assembly and the unlocking element of the locking bolt, illustrated in figure 1 mortise lock, which is designed and operates according to one embodiment of the present invention,

on figv shows a simplified enlarged view of the gear used to move the components illustrated in figure 1 mortise lock, which is designed and operates according to one of the embodiments of the present invention,

figure 2, 2A, 2B and 2B shows simplified views corresponding to those shown in figures 1, 1A, 1B and 1B of the mortise lock, in which the locking bolt assembly has moved to the unlocked position,

figure 3, 3A, 3B and 3B shows simplified views corresponding to those shown in figures 1, 1A, 1B and 1B of the mortise lock, in which the latch pin has moved to the unlocked position, and

4, 4A and 4B show a simplified side view, a cross-sectional view and an enlarged view, respectively, of the gear of the lower cylindrical lock illustrated in FIG. 1 of a mortise lock, which is designed and operates according to one embodiment of the present invention.

Detailed Description of Embodiments

Refer to FIGS. 1-1B, which illustrate a mortise lock 10 designed and operable in accordance with one non-limiting embodiment of the present invention.

The mortise lock 10 has a housing 12 in which the lock device of the lock is placed and a protective plate 14. The mortise lock 10 is applicable for use in a variety of doors, for example, but not exclusively hinged doors and sliding doors. Usually a mortise lock 10 is designed for installation with an insert inside the door frame. The lock is installed inside the door so that its body 12 is hidden except for the protective plate 14, which is usually located flush with the edge of the door opposite the edge of the door on which the hinges are located. Mortise lock 10 has holes in which other hardware of the lock is included, including a hole 16 for the handle (usually not round, for example, square) and a hole 18 for the lock cylinder. A handle rod (not shown) may be inserted into the handle hole 16 (not shown) for pushing (opening) the latch (latch pin) 20. The lock cylinder 19 may enter the lock cylinder 18 (shown in FIGS. 4-4B), which can rotate the push deadbolt wheel 22 (shown in FIGS. 1, 4 and 4A, and also partially shown in FIG. 1A) for pushing the locking bolt assembly 24 (as well as the latch 20 and other elements of the lock, as described later) after the lock cylinder 19 is inserted and the corresponding key is turned. The locking bolt assembly 24 is also referred to as the locking bolt or locking bolts 24.

In one embodiment of the present invention, the mortise lock 10 has an aperture 26 for an auxiliary cylinder lock, which includes an auxiliary cylinder lock (not shown) for actuating the auxiliary locking bolt 28 and the latch 20. The auxiliary locking bolt 28 can be attached to the guide element 30, which is able to slide into and out of housing 12. The sliding movement of the guide member 30 may be guided by a pin 32 that fits into a groove 34 made in the guide member 30. The guide member 30 may have gear teeth 36 that engage with a push wheel (not shown) of an auxiliary cylindrical lock. An auxiliary cylinder lock may be useful, for example, for a homeowner who has a maid having a key suitable for a cylinder that enters the cylinder hole 18. The homeowner does not provide the servant with the key to the auxiliary cylinder lock. Thus, the homeowner can lock the auxiliary cylinder lock and go on vacation, being sure that the servant will not be able to get into the house without permission, using his key to another lock.

Refer to FIGS. 4 and 4A, which illustrate the gearing of the lower cylinder lock 19 of the mortise lock 10, which is designed and operates according to one embodiment of the present invention. As mentioned above, the cylindrical lock 19 rotates the ejector bolt wheel 22, which is attached to the end of the toggle switch of the cylindrical lock 19. The ejector bolt wheel 22 is in gear connection with the gear wheel 62 (or simply gear 62). The pusher wheel 22 can be a complete gear wheel, i.e. with gear teeth around the entire circumference of the wheel 22. The pusher wheel 22 can have a tongue 29, which can actuate the locking elements, as is known from the art. In one of the preferred embodiments (illustrated embodiment), the ejector wheel 22 has both gear teeth and the tongue 29, and at the location of the uvula 29, the tooth rupture of the gears of the ejector wheel 22 is formed. If the ejector wheel 22 was engaged only with gear 62, the wheel 22 would not report rotation of the gear 62 at the point of rupture of the gear teeth of the ejector bolt of the wheel 22. In order to ensure the continuity of the gear drive with the ejector the bolt 22 on the gear 62, the ejector bolt 22 is also in gear connection with the spur gear 61, which engages with another spur gear 60, which in turn is engaged with the gear 62. Thereby the rupture of the gear teeth, the ejector bolt wheel 22 transmits movement to the gear wheel 62 through spur gears 61 and 60. Therefore, the ejector bolt wheel 22 constantly transfers power to the gear 62.

Gear 62 is engaged with another gear 64 (or simply gear 64). Both gears 62 and 64 have two pins that protrude from their front surface. Gear 62 has two pins 66 that protrude on both sides of the gear. The pins 66 extend along the central axis of each gear symmetrically around the center of rotation of the gear, for example, at a distance of 10 mm from each other. Gear 64 has two pins 67, which protrude on one side of the gear, for example, at a distance of 7 mm from each other (gears 62 and 64 without pins 66 or 67 are identical - they have four mounting holes, two holes at a distance of 10 mm each from each other and two others at a distance of 7 mm from each other). The pins 66 and 67 convert the rotational movement of the gears 62 and 64, respectively, into a rectilinear motion to actuate the locking pins and elements, as described below.

Turning again to FIGS. 1-1B. A gear rack 68 is attached to the locking bolt assembly 24. The pins 66 of the gear 62 are engaged with the gear rack 68. As the gear 62 rotates, the pins 66 alternately enter the grooves and exit the grooves of the gear rack 68 and thereby give a direct motion to the gear rack 68 and at the same time, the locking bolts 24 are forced to enter and exit the housing 12.

The gear 64 by means of the pins 67 is in gear connection with the first gear rack 70 attached to the lower locking pin 72, which enters the housing 12 and leaves the housing 12 due to the guiding action of the pin 74 in the groove 76. The gear 64 by the same pins 67 also is in gear connection with a second gear rack 80 attached to the upper locking pin 82, which enters the housing 12 and leaves the housing 12 due to the guiding action of the pin 84 in the groove 86. As the gear 64 rotates, the pins 67 alternately enter anavki and exit the grooves of gear racks 70 and 80 and thereby inform linear motion of the toothed rack 70 and 80 and simultaneously cause locking pins 72 and 82 enter the housing 12 and out of it.

Figure 1 shows the crossbar, completely out of the housing 12, that is, in the locked position. Figure 2 shows the crossbar, partially released (partially retracted) from the housing 12, that is, still in the unlocked position. Figure 3 shows the crossbar, fully retracted into the housing 12, that is, in the unlocked position.

In one of the preferred embodiments of the present invention, there is provided a device 50 for interacting with a locking bolt, which gives the user a “sensation” (tactile indication) of the movement of the gear rack 68, which moves the locking bolts 24 into and out of the housing 12. The device 50 for human interaction with the locking bolt is best shown in figb, 2B and 3B.

In the illustrated non-limiting embodiment, the device 50 for interacting with the locking bolt has a generally rectangular body 52 with a straight edge protrusion 53 and a beveled edge 54. A bias device 51, such as a coil spring, abuts the protrusion 53. The device 50 for interacting with the locking bolt is capable of sliding in the recess 55, which has a beveled surface 57 corresponding to the shape and size of the beveled edge 54. The device 50 for interacting with the locking bolt also has an inner beveled surface 56.

As mentioned previously, the pins 66 of the gear 62 are engaged with the gear rack 68. These pins 66 protrude on the other side of the gear 62 and alternately press against and move away from the beveled surface 56. As shown in FIG. 1B, one of the pins 66 (the pin indicated by 66 in the drawing) almost went into the groove 58 of the gear rack 68 on one side of the gear 62, and on the other side of the gear 62 the same pin 66 abuts against the inner beveled surface 56 As shown in FIG. 2B, the gear 62 is rotated counterclockwise, as a result of which the pin 66 goes into the groove 58 and moves the gear rack 68 to the right according to the drawing, that is, in the direction of the interior of the housing 12. At the same time, the pin 66 presses to the inner beveled surface 56 and makes the device Property 50 for the human interaction with the locking bolt to lower, overcoming the resistance of the spring 51, and to move the beveled surface 57 away from the inner beveled surface 56. As shown in Fig.3B, the gear 62 is rotated counterclockwise, and the pin 66 leaves the groove 58 as it moves the gear rack 68 even further to the right in the direction of the inner space of the housing 12. The spring 51 pulls the device 50 for human interaction with the locking bolt, and the beveled surface 57 again abuts against the inner beveled surface 56. The user feels when the beveled surface 57 abuts against the inner beveled surface 56. Thereby, the user "senses" every turn of the key in the lock cylinder and, therefore, "senses" the movement of the locking bolts 24. In addition, when the beveled surface 57 abuts into the inner beveled surface 56, a geometric blocking of the device 50 for human interaction with the locking bolt and the locking bolts 24 occurs.

Turning again to FIGS. 1 and 1A. With the locking bolt assembly 24 by means of a pin 93, which is included in the L-shaped groove 95 in the gear rack 68, the pusher 92 of the latch pin is connected. The pusher 92 of the latch pin has an eye 94. The pusher 92 of the latch pin is pivotally mounted on the upper part 103.

As shown in FIG. 1, the pin 93 is at the far right end of the groove 95. After turning the lock to the position shown in FIG. 2, the pin 93 moves to the far left end of the groove 95, but the latch pin pusher 92 has not yet moved.

When the locking bolt assembly 24 moves to the unlocked position (with further rotation of the key in the cylinder lock), as best shown in FIGS. 3 and 3A, the L-shaped groove 95 pushes the pin 93 and moves the eye 94 to the right according to the drawings. The eye 94 is in a position in which the tongue 29 of the ejector wheel 22 pushes and pushes it up

As a result of the upward movement of the pusher 92 of the latch pin (and in this case, when the key is rotated in a cylindrical lock), the upper part 103 pushes up the shoe 104 of the lever 106. The lever 106 rotates around the rod 108 and has a nozzle 110 that is pressed against the shoulder 112 of the latch pin, which biased by the spring 114. The arm 112 of the latch pin 112 rotates with the handle hole 16 and moves the latch 20 to the unlocked position to open the door.

It is understood that various features of the invention, which for clarity are described in the context of individual embodiments, may also be used in combination in a single embodiment. In contrast, various features of the invention, which are described for brevity in the context of a single embodiment, can also be used individually or in any applicable subcombination.

Claims (8)

1. Mortise lock (10), containing:
case (12) and
locking bolt (24) and locking pins (72, 82) capable of entering and leaving said housing (12), respectively, in an unlocked and locked position by means of a pushing bolt of a wheel (22),
characterized in that the pushing bolt wheel (22) is in gear connection with a gear (62), which has two pins (66) protruding from one of its surfaces, while the pins (66) of said gear (62) engage a gear rack (68) connected to the said locking bolt (24), and as said gear (62) rotates, the pins (66) alternately enter the grooves and exit the grooves of the said gear rack (68) and thereby direct the linear movement of said gear rail (68) and force the said locking bolt (24 ) enter and exit the said building (12),
said gear (62) is engaged with another gear (64), which also has two pins (67) protruding from one of its surfaces, while the pins (67) of said gear (64) are engaged with the first gear rack ( 70) and a second gear rack (80), respectively, which are attached to the said locking pins (72, 82) of the lock, and as the said gear (64) rotates, the pins (67) alternately enter the grooves and exit the grooves of the first and second toothed racks (70, 80) and force said locking pins (72, 82) to enter into yanuty housing (12) and out of it. 2. The mortise lock (10) according to claim 1, further comprising a device (50) for interacting with the locking bolt, which provides tactile indication of the movement of said gear rack (68), which moves the said locking bolt (24) inside the housing (12) ) and from it. 3. Mortise lock (10) according to claim 2, in which said device (50) for interacting with a locking bolt is made with an internal beveled surface (56) and has a protrusion (53) and a beveled edge (54), while in said the protrusion (53) abuts the biasing device (51), and the said device (50) for interacting with the locking bolt is able to slide in the recess (55) with a beveled surface (57) corresponding to the shape and size of the mentioned beveled edge (54). 4. Mortise lock (10) according to claim 3, in which, as said gear (62) rotates, said pins (66) alternately press against said inner beveled surface (56) and thereby cause said beveled surface (57) to move away from said the inner beveled surface (56), and alternately removed from said inner beveled surface (56) and thereby cause the biasing device (51) to press said beveled surface (57) to said inner beveled surface (56) and provide said tact full indication. 5. Mortise lock (10) according to claim 3, wherein when said beveled surface (57) is pressed against said inner beveled surface (56), said locking bolt (24) is geometrically locked. 6. Mortise lock (10) according to any one of the preceding paragraphs, wherein said ejector wheel (22) has a tongue (29), at the location of which the gear teeth rupture of said ejector wheel (22), wherein said ejector wheel (22) is in gear connection with a spur gear (61), which engages with another spur gear (60), which in turn engages with said gear (62). 7. Mortise lock (10) according to claim 6, in which the pins (66) of said gear (62) protrude from both sides of said gear (62). 8. Mortise lock (10) according to any one of claims 1 to 5, in which the pins (66) of said gear (62) protrude from both sides of said gear (62).

Images