Bar handle with incorporated lock

Abstract

A bar handle with incorporated lock having a tubular element for gripping a handle, installed on a face of a door by way of interposition of at least one spacer element, and a lock which is at least partially contained inside the tubular element. The handle includes a release device for releasing the lock, which is configured to be operated manually with a pusher element installed on the tubular element. the handle comprises a release device for releasing the lock, which is configured to be operated manually with a pusher element installed on the tubular element.

Claims

1. A bar handle with incorporated lock, which comprises: a tubular element, for gripping said handle, installed on a face of a door by way of interposition of: at least one spacer element extending substantially perpendicular to the tubular element, a lock which is at least partially contained inside said tubular element, said handle comprising a release device for releasing said lock, which is configured to be operated manually with a pusher element installed on said tubular element, wherein the release device is positioned in the at least one spacer element.

2. The bar handle according to claim 1, wherein said pusher element is a vertical bar with a C-shaped profile in cross-section and with the cavity directed toward the inside of said tubular element, where a profiled element, also C-shaped in cross-section, is associated, in the cavity of said profiled element there being a longitudinally-extended plate-like slider, on said profiled element and on said slider there being slots with pins which pass transversely through them both and are fixed with respect to said tubular element, and on said slider there being slots with pins coupled to said profiled element, said slots and said pins acting to guide the translation of said profiled element and said slider within said tubular element.

3. The bar handle according to claim 2, wherein on sides of said profiled element there are two mirror-symmetrical pairs of horizontal slots, a first, lower horizontal pair and a second, upper horizontal pair.

4. The bar handle according to claim 3, wherein said longitudinally-extended plate-like slider has a first vertical slot at said first pair of horizontal slots of said profiled element and a second vertical slot at said second pair of horizontal slots, said first pair of horizontal slots and said first vertical slot being passed through simultaneously by a same first pin, said second pair of horizontal slots and said second vertical slot being passed through simultaneously by a same second pin.

5. The bar handle according to claim 2, wherein on said longitudinally-extended plate-like slider there are a first and a second oblique slots, which are passed through respectively by a first pin and by a second pin.

6. The bar handle according to claim 2, further comprising a lower support and an upper support which are connected by way of a pair of parallel rods which are spaced apart, said longitudinally-extended plate-like slider being installed between said lower support and said upper support.

7. The bar handle according to claim 2, further comprising a gearwheel which interacts with two mutually opposite rack elements, a first rack element coupled with an upper end thereof to a lower end of said longitudinally-extended plate-like slider and a second rack element coupled with a lower end thereof to a counterweight.

8. The bar handle according to claim 1, further comprising a transmission rod inside said tubular element, which is coupled with a first end thereof to a tip element and with a second end thereof to said release device.

9. The bar handle according to claim 8, wherein said lock comprises a guide within which said tip element is adapted to slide.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further characteristics and advantages of the disclosure will become better apparent from the detailed description of a preferred, but not exclusive, embodiment of the bar handle according to the disclosure, which is illustrated, by way of non-limiting example, in the accompanying drawings wherein:

(2) FIG. 1 is a perspective view of a bar handle according to the disclosure in the locked configuration;

(3) FIG. 2 shows a bar handle as in FIG. 1, in which the release device inside the tubular element is made partially visible;

(4) FIG. 3 is an exploded perspective view of a part of the release device;

(5) FIG. 4 is a cross-sectional view of the part of the release device shown in FIG. 3, in the locked configuration;

(6) FIG. 5 shows the part of the release device as in FIG. 4, in the unlocked configuration;

(7) FIG. 6 is a cross-sectional view of a part of the lock;

(8) FIG. 7 is a perspective view of an element of the handle according to the disclosure; and

(9) FIG. 8 is another perspective view of the element of the handle according to the disclosure.

DETAILED DESCRIPTION OF THE DRAWINGS

(10) With reference to FIGS. 1-8, the handle according to the disclosure, generally designated by the reference numeral 10, comprises: a tubular element 12, for gripping the handle 10, installed on the face of a door leaf by way of interposition of: at least one spacer element 13, three in the case shown, a lock 11 which is at least partially contained inside the tubular element 12.

(11) The tubular element 12 and the spacer elements 13 are installed on the door leaf of the door which is directed toward the inside of the environment in which it is installed.

(12) The tubular element 12 is installed in the vertical position.

(13) The handle 10 comprises, on the opposite face of the same door leaf, another tubular element 14 and at least one other spacer element 15, three installed correspondingly to the previously-mentioned elements.

(14) The spacer elements 13 and 15 are substantially tubular as well and are installed perpendicular to the tubular elements 12 and 14 in order to support and connect the latter items to the door.

(15) For each tubular element there are three spacer elements, at different heights, since the tubular elements are installed vertically.

(16) In particular, in the embodiment shown, there are first spacer elements 13a near the opposite ends of the tubular element 12 and a second spacer element 13b at a height comprised between the range of the two heights of the other spacer elements 13a, within which a device 16 for actuating the lock 11 is installed.

(17) Two first spacer elements 15a are installed near the opposite ends of the tubular element 14, while a second spacer element 15b is installed correspondingly to the second spacer element 13b which supports the device 16, this element 15b being provided with a receptacle 17 for a key-operated cylinder, as indicated in FIG. 6.

(18) The bar handle 10 according to the disclosure can be installed both on leaf doors and on sliding doors, in the latter case when the sliding is to the right, with respect to what is shown in FIGS. 1 and 2 where the direction of sliding is indicated with the arrow A. The direction of thrust is the same as the direction of movement of the (sliding) door.

(19) The bar handle 10 comprises a release device 18 for releasing the lock 11, which can be operated manually with a pusher element 19 installed on the tubular element 12, on the face of the door leaf facing inwards.

(20) The pusher element 19 includes a bar operated by a button recessed mechanically inside a special seat, as a result of a manual push to unlock the lock 11.

(21) The pusher element 19 is a vertical bar with a C-shaped profile in cross-section and with the cavity directed toward the inside of the tubular element 12, where a profiled element 20, also C-shaped in cross-section, is associated. The pusher element 19 and the profiled element 20 are mutually coupled, in the manner described below. In the cavity of the profiled element 20 there is a longitudinally-extended plate-like slider 22, and on these two there are slots 21 and 23 with pins 24 which pass transversely through them both and are fixed with respect to the tubular element 12, and on the slider 22 there are slots 26 with pins 27 coupled to the profiled element 20, their ends being inserted into the holes 52. Such slots 21, 23 and 26 and pins 24 and 27 guide the translation of the profiled element 20 and the slider 22 within the tubular element 12.

(22) In particular, on the sides of the profiled element 20 there are two mirror-symmetrical pairs of horizontal slots 21, a first, lower horizontal pair 21a and a second, upper horizontal pair 21b.

(23) In turn, positioned within the cavity of such profiled element 20 is the slider 22, which has a first vertical slot 23a at the first pair of horizontal slots 21 of the profiled element 20 and a second vertical slot 23b at the second pair of horizontal slots 21b. The first pair of horizontal slots 21a and the first vertical slot 23a are passed through simultaneously by a same first pin 24a, while the second pair of horizontal slots 21b and the second vertical slot 23b are passed through simultaneously by a same second pin 24b. The pins 24a and 24b are adapted to slide horizontally in the first 21a and second 21b pairs of slots, and at the same time vertically in the slots 23a and 23b. With the pins 24a and 24b respective bushings 37 made of brass are provided.

(24) The bar handle 10 also comprises a lower support 25a and an upper support 25b within the tubular element 12.

(25) The pins 24a and 24b are fixed respectively in the lower support 25a and in the upper support 25b.

(26) On the slider 22 there are also two oblique slots, first 26a and second 26b, respectively in a lower position and an upper position, between the two aforementioned first and second vertical slots 23a and 23b, with positive inclination toward the inside.

(27) Such oblique slots 26a and 26b are passed through by a first pin 27a and by a second pin 27b respectively, which are held in place between the opposite faces of the profiled element 20. With the pins 27a and 27b bushings 38 made of brass are provided.

(28) The lower support 25a and the upper support 25b are connected by a pair of parallel rods 28 which are fixed at their ends with screws 29 to the two supports 25a, 25b. The two bars 28, in addition to being parallel, are also spaced apart and the slider 22 is installed between them.

(29) The two supports 25a and 25b are substantially C-shaped in cross-section, with the opening directed outward, i.e. toward the pusher element 19, so as to allow a horizontal translation, toward the inside of such element, of the profiled element 20 and of the slider 22. Such supports 25a and 25b are shown individually in the respective FIGS. 7 and 8. In particular, FIG. 7 shows the upper support 25b and FIG. 8 shows the lower support 25a.

(30) The two supports 25a and 25b have respective pairs of tabs 50 and 51 for guiding the slider 22 and which constrain the respective pins 24a and 24b.

(31) As shown in FIGS. 3 to 5, the slider 22 has extensions at its ends, for which there are two covers 30 which close the ends of the profiled element 20 and which are U-shaped, with a slit that allows the two extensions to protrude at the opposite ends of the profiled element 20.

(32) As anticipated, the pusher element 19 and the profiled element 20 are mutually coupled: this is obtained with screws 30a, one at each end, which pass through the element 19, the profiled element and the respective covers 30 in adapted holes.

(33) At the lower end, the slider 22 is provided with an indentation 39, indicated in FIG. 3, which allows the profiled element 20 to perform a horizontal stroke during the pushing of the element 19.

(34) At the lower end the slider 22 is coupled to a first rack element 31a of the lock 11, by way of a pin with a C-clip 41.

(35) The lock 11 comprises a gearwheel 32, with its rotation axis parallel to and/or coincident with the axis of extension of the second spacer element 13b, and which is connected both to the device 16 and to the receptacle 17 of the cylinder, as better described below.

(36) The gearwheel 32 is arranged inside a receptacle 33, which is arranged at the intersection between the through holes of the second spacer element 13b and of the tubular element 12.

(37) The gearwheel 32 interacts with two mutually opposing rack elements of the lock 11: the first rack element 31a and the second rack element 31b.

(38) The slider 22 is also provided with a recess at the lower end, indicated in FIG. 5 with the reference numeral 40, which allows the lifting of the second rack element 31b induced by the activation of the release device 18, during the pushing of the element 19, bringing such rack element 31b with the upper end into the recess 40.

(39) The receptacle 33 has a substantially cylindrical body with two through holes 34 in which the two rack elements 31a and 31b pass through it lengthwise in the vertical direction.

(40) Between the two through holes 34 there is another hole 35, with its axis perpendicular to the previous axes, in which the gearwheel 32 is installed. The hole 35 intercepts the through holes 34, thus the two rack elements 31a and 31b mesh in diametrically opposite positions on the teeth of the gearwheel 32.

(41) The first rack element 31a is coupled with the upper end thereof to the lower end of the slider 22, while the second rack element 31b is coupled with the lower end thereof to a counterweight 36.

(42) The part of the lock 11 with the device 16 and the receptacle 17 of the cylinder is described below.

(43) As shown in FIG. 2, the handle 10 also comprises, inside the tubular element 12, a transmission rod 42 which is coupled with its upper end to a tip element 43 and with its lower end to the release device 18, being pivoted to the upper end of the slider 22, by way of a pin 44.

(44) The lock 11 comprises a per se known guide 45 in which the tip element 43 is adapted to slide, and which is accommodated inside the tubular element 12. The tip element 43 protrudes from the guide 45 and from the tubular element 12 in the closed configuration of the lock 11, as shown in FIG. 1 and in FIG. 2.

(45) FIG. 6 shows a part of the lock 11, in the open configuration, at the device 16 and the receptacle 17 of the cylinder.

(46) This part is substantially per se known.

(47) The gearwheel 32 is mounted on a first pivot 46 and on a shaft 47, which are aligned head-to-head along the axis of rotation of the wheel and are accommodated inside the second spacer element 13b. A second pivot 48 is accommodated inside the second spacer element 15b, aligned with the previous pivots along the same axis. The second pivot 48 is positioned head-to-head with the shaft 47 within a threaded tubular receptacle 49 which connects the two spacer elements 13b and 15b by passing through the door leaf of the door.

(48) By way of a series of tubular receptacles which, in a conventional manner, are mutually connected and installed in the two spacer elements 13b and 15b, the key-operated cylinder and the device 16 are integral. In fact, a rotation imparted to the key inside the cylinder causes the rotation of the first pivot 46 and therefore of the gearwheel 32, as happens with the rotation of the knob 16.

(49) The gearwheel 32 with the rack elements 31a and 31b convert the circular movement of the cylinder and/or of the actuation knob to a linear movement which is transmitted to the rest of the lock.

(50) Operation of the handle, according to the disclosure, is as follows.

(51) The handle 10 is installed, in a per se known manner, in a vertical position on the door leaf of a door with the tubular element 12 on the face thereof facing the inside of the room and the other tubular element 14 on the opposite face and correspondingly to the former.

(52) When the lock 11 is closed, the tip element 43 protrudes from above, externally from the guide 45 and from the tubular element 12, as shown in FIG. 1 and in FIG. 2, in order to be inserted into a dead hole which is conveniently present on the door threshold area.

(53) The mechanism for opening and closing the lock 11 and the operation of the release device 18 is clear, in particular, in FIGS. 4 and 5.

(54) Pushing the pusher element 19, the release device 18 is activated: the profiled element 20 is pushed toward the inside of the tubular element 12.

(55) The horizontal translation of the profiled element 20 determines the vertical translation of the slider 22, downward in the case shown: such elements are moved with respect to the pins 24a, 24b and 27a, 27b, and are guided by the vertical slots 23a and 23b, horizontal slots 21a and 21b, and oblique slots 26a, 26b.

(56) The slider 22 performs a translational motion, pulling the transmission rod 42, which in turn brings the tip element 43 to translate downward in the guide 45, thus freeing the dead hole on the door threshold area.

(57) Lowering the slider 22 also determines the lowering of the first rack element 31a, which in turn rotates the gearwheel 32 and the device 16.

(58) In a similar manner, the release of the lock occurs in fact by rotating the device 16 or the cylinder using the key.

(59) In practice it has been found that the disclosure fully achieves the intended aim and advantages by providing a quick-release bar handle that is easy to use, with a single manual pushing action, in the same direction of travel as the door, similarly to panic bars installed horizontally on leaf doors.

(60) It should also be noted that the handle can easily be used by persons with limited motor capacities and in particular by persons who have difficulty moving their hands, it being unnecessary to grasp or turn knobs, handles or other actuation devices in order to obtain the release of the lock.

(61) It should also be noted that the release device in the handle is capable of reducing the force to be applied on the pusher element and at the same time maximizing the travel of the tip element.

(62) Also, it should be noted that the handle according to the disclosure is installable on sliding doors but also on leaf doors.

(63) The disclosure thus conceived is susceptible of numerous modifications and variations, all of which are within the scope of the appended claims. Moreover, all the details may be substituted by other, technically equivalent elements.

(64) In practice the materials employed, provided they are compatible with the specific use, and the contingent dimensions and shapes, may be any according to requirements and to the state of the art.