DE19949185A1 - Hinge or gate hook device for door has vertical support elements and includes rotating cylinder moving in two fixed cylindrical parts - Google Patents

Abstract

The door (100) has a vertical support plate (102) screwed to it and a second, similar plate (103) is screwed to the door frame. The rotating cylindrical part (104) is rigidly connected to the edge of the door support plate and surrounds a shaft (114) which can rotate. It has an enlarged bottom end (108) fitting into a bush (106) and there is a bush at the top and a latching device with a cam (126) and with a helical torsion spring (120).

Description

The invention relates to a door hinge, more specifically a sol ches installed on a door in a state in no torsional moment on a gate in it sion spring acts and that enables the torsion mo ment of the spring through a separate elasticity adjustment to enable installation the spring and the elasticity setting for this on a easy and fast way to do what makes it possible Door in terms of its opening and closing speed adjust in a more subdivided way, the door evenly and automatically opened by a small force is closed at a low, predetermined speed.  

A door hinge is used to turn a door to hold on a door frame. To do this includes a coulter nier a pair of vertical holding elements, the vertical Direction side by side, or a pair of hori zontaler holding elements, which in the horizontal direction next are arranged one another. In a pair horizontal or vertical holding element is a holding element on a door attached while the other holding element on the door frame be is consolidated.

For door hinges with the simple above Structure occurs a problem in that the closing the same is associated with effort, since it is not automatic close the table. To overcome this problem, e.g. B. a hydraulically operated, automatic door closing device used. However, such a device is expensive and it's difficult to put on a door.

More recently, door hinges with a torsion spring the known that allow a door to be closed automatically conclude. Since such a door hinge is cheap, can it can be widely applied.

However, this type of door hinge suffers from defects in that the installation and the elasticity are difficult because the hinge is in one condition must be attached to the door and the door frame in which the desired torsional moment on the torsion spring works; therefore the adjustment of the torsional moment cannot just run. If the torsional moment is not is set correctly, a person can quickly Closing the door will hurt you. Furthermore occurs at one use such known door hinge in a door the person easily feels that the function is unsatisfied because the door is either difficult or very difficult  can be opened easily or closes too quickly.

The invention is based on the object, a door hinge to create that attached to a door in a state in which there is no torsional moment on an existing one Torsion spring acts, and that an adjustment of the gate sionsmoments through a separate elasticity adjustment enables, thereby the installation and the elasticity setting can be carried out quickly and easily that can.

Another object of the invention is a door hinge to create a door with a more subdivided way in terms of their opening and closing speeds can be put.

Yet another object of the invention is a coulter to create a door with a small force opened and automatically with a low predetermined Ge speed can be closed.

This task is through the door hinges according to the beige added independent claims 1, 12 and 14 solved. Advantage Strong designs and further training are the subject dependent claims.

Due to the features of the invention, the torsion adjustment can be done quickly and easily in one state, in which there is no torsional moment on the torsion spring acts because the torsional moment of the spring is thereby set is that a tool in a tool insertion groove of an Ab deck elements is introduced and with this a rotation axis is rotated, or that a first outward flange part a second cam element is detected and a second The ratchet wheel is raised by turning the second cam element  will. This is the practical value of the door hinge increases and there is no way that the door is open closes quickly and injures a human being because that Torsional moment of the torsion spring not set correctly is. In addition, the opening and closing speed door can be set in a more subdivided way, because a door hinge device attached above and below are a pair, the torsion springs of which Door hinge devices receive forces in opposite directions set directions act, the torsional moments independent can be set pending; it also makes the Door opened evenly by a small force and auto matically and slowly closed. In addition, the Rotational speed of the axis of rotation, d. H. the public Opening and closing speed of the door on better below shared way, because in part of the Rota tion axis with a larger diameter a device for separate and additional control of the rotation speed is present.

The above tasks and other features and advantages of Invention will become apparent upon reading the following detailed Be spelling in connection with the drawings more clearly.

Fig. 1 is a partially sectioned longitudinal section to illustrate the overall structure of a door hinge according to a first embodiment of the invention;

FIG. 2 is an exploded perspective view illustrating various components of the door hinge of FIG. 1;

Fig. 3 is a partially sectioned sectional view for explaining a process for increasing the torsional moment of a torsion spring by rotating an axis of rotation in the clockwise direction, thereby causing the torsion spring to be wound with increased elastic force;

Fig. 4 is a partially sectioned sectional view for explaining a process for reducing the torsional moment of the torsion spring by lifting a cylindrical Nockenele element and a cylindrical ratchet wheel in the axial direction to ensure that the torsion spring is relaxed so that its elastic force decreased;

Fig. 5 is a perspective view illustrating configurations of an annular Rastenrads and a cylindrical Rastenrads, the sheet of the invention are in accordance with modifi;

Fig. 6 is a perspective view illustrating a state in which a door hinge is installed according to a second embodiment of the invention between the upper end of a door and a door frame;

Fig. 7 is a partially sectioned longitudinal section to illustrate the overall structure of the door hinge of Fig. 6;

Fig. 8 is to illustrate various Veran the door hinge of Figure 6 in an exploded perspective view build construction components.

Fig. 9 is a partially sectioned longitudinal section to illustrate the overall structure of a door hinge according to a third embodiment of the invention;

FIG. 10 is an exploded perspective view for illustrating various components of the door hinge of FIG. 9;

Fig. 11 is a partially sectioned longitudinal section for illustrating a state in which a first torsion spring and a second torsion spring in the third embodiment of the invention are wound in opposite directions;

Fig. 12 is a perspective view for illustrating a door hinge according to a fourth embodiment of the invention; and

FIG. 13 is a partially sectioned longitudinal section to illustrate the overall structure of the door hinge of FIG. 12.

A preferred embodiment is now described in more detail game of the invention referred to in the accompanying Drawings is illustrated. Wherever possible are in all drawings and the associated description used the same reference numbers, the same or similar to mark parts.

The first embodiment is described below with reference to FIGS. 1 to 5. The door hinge 100 according to this first embodiment includes a pair of vertical holding members 102 and 103 . The first vertical support member 102 is fixed to a door to rotate with it, and the second vertical support member 103 is fixedly attached to a door frame. A rotating cylindrical member 104 is attached in the central part in the longitudinal direction of the first vertical holding member 102 , at one end in the width direction thereof, facing the second vertical holding member 103 . A pair of fixed cylindrical parts 106 and 107 are integrally attached to the two ends of the second vertical holding member 103 in the longitudinal direction and at one end in the width direction in alignment with the first vertical holding member 102 . The pair of fixed cylindrical members 106 and 107 are aligned with the lower and upper ends of the rotating cylindrical member 104 , and washers 158 and 159 are provided between each fixed cylindrical member 106 and 107 and the rotating cylindrical member 104 , respectively. A pin element 108 is inserted into the first fixed cylindrical part 106 from bottom to top. A formed at the upper end of the pin member 108 Ge threaded portion is screwed into a thread on the inner periphery of the lower end of the rotating cylindrical member 104 and thereby attached to it. The lower end of the pin member 108 is formed with a head portion 110 , and the upper end thereof is formed with a Halteachsenab section 112 which extends upward under reduced diameter. When the pin member 108 is screwed into the rotating cylindrical part 104 , the head portion 110 thereof sits on the lower end of the first fixed cylindrical part 106 .

The lower end of an axis of rotation 114 is inserted into the rotating cylindrical part 104 from top to bottom. The middle section of the axis of rotation 114 is formed with a section 116 with a larger diameter. The lower end of the axis of rotation 114 sits on the free end of the holding axis section 112 of the pin element 108 . The lower end of the axis of rotation 114 and the free end of the support axis portion 112 are provided with an insertion groove 168 and 169 , respectively. The two ends of a round bar 170 are inserted into the insertion grooves 168 and 169 , and between the bottom surfaces of the insertion grooves 168 and 169 and the two ends of the round bar 170 there are balls 118 and 119, respectively, for guiding the rotation of the axis of rotation 114 . In the rotating cylindrical part 104 , a torsion spring 120 is wound around the outer peripheral surface of the axis of rotation 114 . The upper end of this torsion spring 120 is fixed in a spring mounting groove which is formed on the underside of the portion 116 of the axis of rotation 114 with a larger diameter so as to be fixed, and the lower end of the torsion spring 120 is inserted in another spring mounting groove which is formed in the upper end surface of the pin member 108 so as to be fixed to who. In FIG. 1, the torsion spring 120 is a left he rum spiral torsion spring. Accordingly, when the rotation axis 114 is rotated in the clockwise direction, a force in the winding direction of the torsion spring 120 acts on it, thereby increasing its torsional moment. On the other hand, when the axis of rotation 114 is rotated in the counterclockwise direction, a force acts on the torsion spring 120 in the bending direction thereof, thereby reducing its torsional moment. Above the section 116 with a larger diameter, the outer peripheral surface of the axis of rotation 114 is provided with at least one web groove 146 . When the axis of rotation 114 is inserted into the rotating cylindrical part 104 , essentially the central section of the section 116 with a larger diameter projects upward above the washer 159 located above.

In the second cylindrical part 107 of the second vertical holding element 103 , an annular ratchet wheel 122 and an annular cam element 126 are inserted from top to bottom. The ring-shaped ratchet wheel 122 sits on the top of the section 116 of the larger-diameter axis of rotation 114 , and the ring-shaped cam member 126 sits on the ring-shaped raster wheel 122 . The inner circumferential surface of the second fixed cylindrical part 107 is provided with a groove 152 , and the outer circumferential surfaces of the ring-shaped toothed wheel 122 and the ring-shaped cam member 126 are provided with ridges 154 and 155 , respectively. These webs 154 and 155 of the ring-shaped index wheel 122 and the ring-shaped Nockenele element 126 are inserted into the groove 152 of the second fixed cylindri's part 107 . Since the second fixed cylindrical member 107 is held in a state in which it is fixed to the door frame, the ratchet wheel 122 and the cam member 126 cannot be rotated in the circumferential direction, but can only be shifted in the axial direction. On a peripheral portion of the ratchet wheel 122 , which is displaced radially and inward with respect to the associated outer peripheral surface by a distance which corresponds to the thickness of the cam element 126 sitting thereon, the raster wheel 122 is formed with a plurality of first axial catches 124 . At least two cam projections 128 are formed on the top of the cam member 126 in such a manner that they extend upward in the axial direction.

On the annular cam element 126 sits a cylindri cal cam element 140 , on the underside of which at least two cam trenches 132 are formed, into which the cam projections 128 of the annular cam element 126 can each engage. The upper end of the cylindrical cam member 130 is provided with a first outward flange portion 134 which projects radially outward. Within the first outward flange portion 134 , the inner peripheral surface of the cylindrical cam member 130 is provided with a stepped portion 136 . The first outward flange section 134 of the cylindrical cam member 130 sits on the upper end of the second fixed cylindrical part 107 . In the cylindrical cam member 130 , a cylindrical index gear 138 is inserted, the upper end of which is provided with a two-th outward flange portion 142 which sits on the stepped portion 136 of the cylindrical cam member 130 . On the underside of the cylindrical indexing wheel 138 , a plurality of second axial notches 140 are formed which can engage with the plurality of first axial notches 124 of the ring-shaped racing wheel 122 . The inner peripheral surface of the cylindrical indexing wheel 138 is provided with at least one web 144 . The other end of the axis of rotation 114 extends through the ring-shaped index wheel 122 , the ring-shaped cam element 126 , the cylindrical cam member 130 and the cylindrical index wheel 138 upwards. By the fact that the web 144 of the cylindrical Rastenrads engages the Stegnut 146 of the rotational axis 114 138, the cylindrical Rastenrad 138 may be integral with the Rota tion axis are rotated 114th Since the second outward flange portion 142 formed on the cylindrical lawn gear 138 is seated on the stepped portion 136 formed in the cylindrical cam member 130 , when the first outward flange portion 134 of the cylindrical cam member 130 sitting on the upper end of the second fixed cylindrical part 107 can be detected and is rotated, the cylindri cal cam member 130 and the cylindrical index wheel 138 are integrally moved in the axial direction along the axis of rotation 114 , while the cam trenches 132 of the cylindrical cam member 130 slide on the cam projections 128 of the annular cam member 126 .

Both the first axial catch 124 and the second axial catch 140 are formed with an inclined surface and a perpendicular surface. In Fig. 1, the second axial detent, which is engaged with the first axial detent 124 , can be rotated in the clockwise direction due to the fact that its inclined surface slides on the inclined surface of the first axial detent 124 . On the other hand, it cannot be rotated counterclockwise due to the fact that its vertical surface is brought into contact with the vertical surface of the first axial catch 124 . Although it has been explained above that the ring-shaped index wheel 122 and the cylindrical index wheel 138 have first axial catches 124 and second axial catches 140 , which each have an inclined and a vertical surface, it should be noted that the ring-shaped index wheel 122 and the cylindrical indexing gear 138 may include a plurality of first axial notches 125 and a plurality of second axial notches 141 , each having a configuration that matches that of a conventional gear.

A cover element 148 is screwed onto the other end of the axis of rotation 113 , which extends upward through the cylindrical indexing wheel 138 . Between the cover member 148 and the cylindrical index wheel 138 , a screw spring 150 is inserted to push the latter down, ie in a direction in which the second axial catch 140 engages with the first axial catch 124 . The upper end surface of the cover member 148 is provided with a tool insertion groove 156 . By inserting a tool into the same and by rotating the tool, the rotation axis 114 can be rotated. On the outer peripheral surface of the cover member 148 , a protective cap 160 is screwed up. The protective cap 160 is used to protect a number of components that protrude from the second fixed cylindrical part 107 .

The door hinge 100 constructed in the above manner according to the first exemplary embodiment of the invention is mounted on the door and on the door frame in a state in which no torsional moment acts on the torsion spring 120 , where the assembly operations can be carried out in a simple manner. If it is necessary to perform operations to adjust the elasticity of the door hinge, that is, the torsion spring 120 after the completion of the assembly processes for the door hinge 100 , this can be realized in the manner described below.

If it is desired to increase the elasticity, ie the elastic force exerted by the hinge 100 , the protective cap 160 is unscrewed from the cover element 148 , and the latter is inserted into the tool insertion groove 156 in it after a tool such as a wrench or the like was introduced, rotated by turning the tool in the clockwise direction (see Fig. 3). When the cover member 148 is rotated in the clockwise direction, the rotation axis 114 integrally attached to it is also rotated in the clockwise direction. Furthermore, a force in the clockwise direction acts on the cylindri raster wheel 138 , since the web 144 formed on the inner peripheral surface thereof engages in the web groove 146 , which is formed on the outer peripheral surface of the axis of rotation 114 . Since the oblique surface of the second axial detent 140 of the cylindrical detent gear 138 slides on the oblique surface of the first axial detent 124 of the annular detent gear 122 , the cylindrical detent gear 138 is rotated in the clockwise direction. Here, since the clockwise rotating second axial detent 140 passes at the upper end of the corre sponding first axial detent 124 , the second axial detent 140 is displaced upward along the top of the corresponding first axial detent 124 by the biasing force of the coil spring 150 . Therefore, counter-clockwise rotation of the second axial detent 140 , which is shifted downward, by the fact axis is prevented from bringing the vertical surface of the second axial detent 140 into contact with the vertical surface of the first axial detent 124 . Since this prevents rotation of the axis of rotation 114 in the counterclockwise direction, the torsion spring 120 , the upper end of which is attached to the section 116 of the axis of rotation 114 with a larger diameter, and the lower end of which is attached to the pin element 108 by an angle in the winding direction around which the axis of rotation 114 is rotated in the clockwise direction, whereby its torsional moment increases. Accordingly, the torsional moment of the torsion spring of the 120 grows more, the larger the number of the first axial detents 124 that pass the second axial detent 140 while being rotated in the clockwise direction.

If it is desired to reduce the elasticity, ie the elastic force of the door hinge 100 , the first outer flange portion 134 of the cylindrical cam member 130 , which sits on the upper end of the second fixed cylindrical part 107, is gripped by hand and in the Twisted clockwise or counterclockwise (see Fig. 4). When the first outward flange is rotated in the clockwise or the counterclockwise direction 134, the cylindrical cam member 130 is lifted along an inclined surface of the cam projection 128 of the annular cam member 126th When the cylindrical cam member 130 is raised, since the second outer flange portion 142 of the cylindrical index gear 138 is seated on the stepped portion 136 of the cylindrical cam member 130 , and since the web 144 formed on the inner peripheral surface of the cylindrical index gear 138 is inserted into the in the Outer circumferential surface of the axis of rotation 114 engages formed groove 146 , the cylindrical index wheel 138 is displaced upward in the axial direction along the axis of rotation 114 , as a result of which the engagement between the plurality of first axial catches 140 of the ring-shaped index wheel 122 and the plurality of second axial catches 140 of the cylindrical Rastenrads 138 is canceled. Since the rotational axis 114 can be freely rotated in the counterclockwise direction by the torsional moment of the torsion spring 120 which is in a state in which it is wound up, the torsional moment thereof can be reduced according to an angle by which the rotational axis 114 is in rotated counterclockwise.

A door hinge 100 shown in FIG. 1 is used so that it is opened by turning in the counterclockwise direction, the elasticity, ie the elastic force of the door hinge 100 , more precisely the torsion spring 120 , in the manner described above represents is. In other words, when the door is rotated counterclockwise, the first vertical support member 102 attached to the door is also rotated integrally in the counterclockwise direction at the lower end of the rotating cylindrical portion 104 of the first Ten vertical holding member 102 attached pin member 108 is also rotated integrally in the counterclockwise direction. That the lower end of the torsion spring 120 is fastened to the Zap fenelement 108 , it receives a force acting in the direction of win, whereby its torsional moment increases. After that, when the door is released, it rotates automatically in the clockwise direction towards the closed position due to the torsional moment of the torsion spring 120 , which was increased when the door was opened.

According to the present embodiment of the invention, the section 116 of the rotary ash 114 is provided with a larger diameter with a circumferential groove 162 . A pair of semi-circular washers 164 is inserted into the circumferential groove 162 , which are pressed with a predetermined squeezing force by a screw 166 against the bottom of the circumferential groove 162 . The screw 166 extends through the wall of the rotating cylindrical part 104 of the first holding element 102 . Depending on the extent to which the pair of semi-circular washers 164 is pressed against the bottom of the circumferential groove 162 , the rotational speed of the axis of rotation 114 , ie the opening and closing speed of the door, can be adjusted in a better divided manner. For this precise adjustment of the opening and closing speed of the door, a friction-resistant and heat-resistant lining is provided on the inner peripheral surface of each semicircular washer 164 .

With reference to FIGS. 6 through 8, the second exporting the invention will now be described approximately, for example.

Since the structure of a door hinge 200 according to this second embodiment is similar to that of the door hinge 100 according to the first embodiment above, the following explanations focus on those components which are different, and the same reference numerals are used to represent the same parts. The door hinge 200 of the present embodiment includes a pair of horizontal holding members 202 and 203 . The first horizontal support member 202 is attached to a door 212 to rotate integrally therewith, and the second horizontal support member 202 is fixed to a door frame 214 . The upper end of a rotating cylindrical part 104 is fixed to one end of the first horizontal holding element 202 , and the lower end of the fixed cylindrical part 204 is fixed to one end of the second holding element 203 . The fixed cylindrical member 204 is aligned with the upper end of the rotating cylindrical member 104 , and a washer 210 is inserted between the fixed cylindrical member 204 and the rotating cylindrical member 104 . In the rotating cylindrical part 104 a pin member 206 is inserted from the bottom up. Characterized in that a threaded portion 208 formed at the upper end of the pin element 206 is screwed into the inner peripheral surface of the lower end of the rotating cylindrical part 104 , the pin element 206 is fastened to the rotating cylindrical part 104 . The lower end of the axis of rotation 114 sits on the free end of the Zapfenele element 206 , and the other end of the axis of rotation 114 and the upper end of the pin member 206 are formed with insertion grooves 168 and 169 , respectively. The two ends of a round bar 170 are inserted into the pair of insertion grooves 168 and 169 .

Balls 118 and 119 are inserted between the bottom surfaces of the insertion grooves 168 and 169 and the two ends of the round rod 170 in order to guide the rotation of the axis of rotation 114 .

With this embodiment, the same effects are achieved as with the door hinge 100 of the first embodiment, which has a pair of vertical holding members 102 and 103 .

At the hand Fig. 9 to 11, the third execution example of the invention will now be described.

Also in this door hinge 300 according to the third embodiment of the invention, the same reference numerals are used to represent the same parts as in the door hinge 100 of the first embodiment. This door hinge 300 has a pair of vertical holding elements 324 and 325 . The first vertical support member 324 is to be attached to a door to rotate integrally therewith, and the second vertical support member 325 is to be fixedly attached to a door frame. A rotating cylindrical member 104 is integrally connected to the central portion in the longitudinal direction of the first vertical holding member 324 in the longitudinal direction thereof and at one end in the width direction thereof, being aligned with the second vertical holding member 325 , and a pair of fixed cylindrical members 106 and 107 are integrally connected with the two ends in the longitudinal direction of one end of the second vertical holding member 325 in the width direction, aligned with the first vertical holding member 324 . The pair fes ter cylindrical parts 106 and 107 is aligned with the lower end or the upper end of the rotating cylindrical portion 104, and between the fixed cylindrical parts 106 and 107 and the rotating cylindrical portion 104 be there are washers 158 and 159th

A fixed center piece 302 is inserted into the central section of the rotating cylindrical part 104 . Since the fixed center piece 302 is fastened to the rotating cylindrical part 104 by means of a screw 304 , the interior of the rotating cylindrical part 106 is divided into a first functional chamber 310 above the fixed central piece 302 and a second functional chamber 312 below the fixed central piece 302 . In the first functional chamber 310 of the rotating cylindrical part 104 and in the second fixed cylindrical part 107 , a first door hinge device 306 is present, and in the second functional chamber 312 of the rotating cylindrical part 104 and the first fixed cylindrical part 106 is a second door hinge device 308 available. The first door hinge device 306 and the second door hinge device 308 are designed such that they are present with plane symmetry while they are centered on the fixed center piece 302 . Since the constructions of the first and second Türscharniereinrich device 306 and 308 are similar to the construction of the above-mentioned door hinge 100 of the first embodiment, with the exception that the one ends of two Rotationsach sen 114 are inserted into grooves that are at the top and Un underside of the fixed central piece are formed 302 to be rotatably supported by the fixed center piece 302, explanations are hereinafter omitted for the respective components of the first and second door hinge means 306 and 308, and instead, the be concentrated sensitive to specifically be mentioned points.

In the present exemplary embodiment, the torsional moment of a first torsion spring 314 in the first door hinge device 306 and the torsional moment of a second torsion spring 316 in the second door hinge device 308 can be set independently. In Fig. 9, the first tor sion spring 314 and the second torsion spring 316 are left-wound torsion springs. Accordingly, when the first vertical support member 324 is attached to the door and the rotating cylindrical member 104 is rotated in the counterclockwise direction, the first upward torsion spring 314 is subjected to a force acting in its winding direction where its torsional moment increases while the second, torsion spring 316 arranged below receives a force which acts in its bending direction, whereby its torsional moment decreases. Accordingly, the door as a whole is subjected to a pair of forces acting in opposite directions. Since the torque of the first torsion spring 314 is increased and the torsion torque of the second torsion spring 316 is reduced, the door can be opened smoothly. On the other hand, if the door is closed, it can be closed slowly because the torsional moment of the first torsion spring 314 decreases and the torsional moment of the second torsion spring 316 increases. It is easy to see that in the initial state, before opening the door, the torsional moment of the second torsion spring 316 must be set smaller than that of the first torsional spring 314 so that the door can be kept in the closed state.

For the first and second torsion springs 314 and 316, torsion springs wound to the right instead of to the left can also be used. However, in this case, the first axial catches of the ring-shaped index gear 122 and the second axial catches 140 of the cylindrical index gear 148 must be opposite, so that the first torsion spring 314 located above receives a force acting in its winding direction while the second , down on the ordered torsion spring 316 receives a force acting in its bend direction when the axis of rotation 114 or the rotating cylindrical part 104 is rotated in the clockwise direction. Again, it is easy to see that in the initial state before the door is opened, the torsional moment of the first torsion spring 314 must be greater than the torsional moment of the second torsion spring 316 in order to be able to hold the door in the closed state.

Also, as shown in FIG. 11, be opposite the presence in the first door hinge means 306 first gate ionsfeder 314 and the presence in the second door hinge means 308 second torsion spring 316 is wound to each other. In Fig. 11, the first is the Torsionsfe 314 as shown to the left torsional coil spring, while the second torsion spring 316 is shown as a right gewun dene torsion spring. Accordingly, when the first and second torsion springs 314 and 316 are wound in opposite directions, both springs receive a force acting in their winding direction when the rotating cylindrical part 104 is rotated in the counterclockwise direction. Accordingly, the load capacity of this door hinge can be improved because the torsional moments of the first and second torsion springs 314 and 316 are shared to hold a door and open / close it.

Referring to Figs. 12 and 13 will now be the fourth execution example of the invention explained.

Since the structure of the door hinge 400 according to the fourth embodiment is substantially the same as that of the door hinge 300 in the third embodiment described above, the following explanation will focus on those points which represent differences, and the same reference numerals and characteristics of the same parts will be used used. The door hinge 400 includes a pair of horizontal support members 402 and 403 . The first horizontal support member 402 is to be attached to a door to rotate integrally therewith, and the second horizontal support member 403 is to be fixedly attached to a door frame. The upper end of a rotating cylindrical member 104 is integrally attached to one end of the first horizontal holding member 402 , and the lower end of the second fixed cylindrical member 107 is integrally connected to one end of the second holding member 403 . A first fixed cylindrical portion 106 is provided under the lower end of the rotating cylindrical portion 104 . The first fixed cylindrical part 106 is integrally connected via a connecting piece 404 to the second fixed cylindrical part 107 . The fixed cylindrical parts 106 and 107 are aligned with the lower and upper ends of the rotating cylindrical part 104, respectively.

Therefore, the same effects are achieved with the present exemplary embodiments as with the door hinge 300 of the third exemplary embodiment, which has a pair of vertical holding elements 324 and 325 .

As described above, the invention provides advantages achieved in that the attachment of a door hinge and adjusting its elasticity, d. H. an on setting process for the torsional moment of the torsion spring simple and quick way to do that because that Door hinge can be mounted on a door in one state, in which no torsional moment acts on the torsion spring, this torsional moment is adjusted by the fact that a tool is inserted into a tool insertion groove and with this a rotation axis is rotated or that a Push rod is depressed and thereby a claw one Claw element out of engagement with a notch of an on is brought up. Accordingly, the usability of the door hinge is raised and there is no possibility that the door closes quickly and kills someone  last, how this can occur when the torsional moment ei ner torsion spring is not set correctly.

In addition, the opening and closing speed the door can be set in a more subdivided manner, and the door is opened evenly by a small force and automatically closed slowly, depending on the top and bottom because there is a door hinge device and the Torsion springs received in these forces, the opposite set directions act, their torsional moments independent are adjustable.

In addition, the opening and closing speed the door in an even better subdivided way the, since facilities for separate and additional tax the rotational speed of the axis of rotation in one Part of the same are available with a larger diameter.

Claims (23)

1. Door hinge ( 100 ) with:

• - A first holding element ( 102 ) which is to be fastened to a door and has a rotating cylindrical part ( 104 );
• - a second support member ( 103 ) to be attached to a door frame and having a pair of fixed cylindrical members ( 106 , 107 ) vertically aligned with both ends of the rotating cylindrical member of the first support member;
• - A pin member ( 108 ) which is inserted into the first fixed cylindrical part of the second holding element and is fixedly connected to one end of the rotating cylindrical part of the first holding element;
• - An axis of rotation ( 114 ), one end of which is inserted through a second fixed cylindrical part of the second holding member into the rotating cylindrical part of the first holding member so as to be rotatably supported by the pin member and the larger diameter central portion;
• - A torsion spring ( 120 ) which is wound in the rotating cylindri's part of the first holding element about the axis of rotation and one end of which is attached to the pin element and the other element at the larger diameter portion of the axis of rotation;
• - A first ratchet wheel, which is inserted into the second fixed cylin drical part of the second holding element in such a way that it cannot twist, being seated on the part of the larger diameter of the axis of rotation and a plurality of first axial notches, which are radially inward hen, has;
• - A first cam element which is inserted into the second fixed cylindrical part of the second holding element in such a way that it cannot twist and sits on the first ratchet wheel, wherein it is provided with at least one axial cam projection ( 128 );
• - a second cam element, one end of which is inserted into the second fixed cylindrical part of the second holding element in such a way that it can rotate and can be displaced in the axial direction, the one end being provided with at least one axial cam recess ( 132 ) is in which the axial cam projection can engage;
• - A second ratchet wheel, which is inserted in such a way in the second te cam element that it can rotate in one piece with the axis of rotation and can be adjusted in the axial direction, one end of which is provided with several second axial ridges can engage in the plurality of first axial notches of the first notch wheel;
• - A cover member ( 160 ), the tena at the other end of the rotation axis, which extends through the first ratchet wheel, the first cam element, the second cam element and the second Ras, is attached; and
• - A coil spring ( 150 ) which is wound between the second Ras tenrad and the cover around the axis of rotation.

2. Door hinge according to claim 1, characterized in that the first and the second holding element ( 102 , 103 ) form a pair of vertical holding elements which are arranged next to one another in the vertical direction. 3. Door hinge according to claim 1, characterized in that the other end of the second cam element is provided with a first outward flange portion which sits on one end of the second fixed cylindrical part of the second hal teelements ( 103 ), the inner peripheral surface of the first outward flange portion with one From stepped section is provided, while the second end of the second ratchet wheel is seen with a second outward flange section, which sits on the stepped section. 4. Door hinge according to claim 1, characterized in that the first ratchet wheel and the first cam element ring have shape and the second cam element and the second Raster wheel have cylindrical shape. 5. Door hinge according to claim 1, characterized in that the inner circumferential surface of the second ratchet wheel is provided with at least one web and the outer circumferential surface of the axis of rotation ( 114 ) between the larger diameter portion and the other end thereof is provided with at least one web groove into which the land engages, the inner peripheral surface of the second fixed cylindrical part is provided with a groove and the outer peripheral surface of both the first ratchet and the first Nockenele element are provided with a web, and wherein the cover element ( 160 ) is provided with a tool insertion groove is. 6. Door hinge according to claim 1, characterized in that the pin element ( 108 ) has a holding axis section which extends into the rotating cylindrical part of the first holding element ( 102 ), with a free end of the holding shaft section and one end of the rotational axis ( 114 ) are provided with a pair of insertion grooves, the two ends of a round rod are inserted into these insertion grooves and a pair of balls are provided between the bottom surfaces of the insertion grooves and the two ends of the round rod to guide the rotation of the axis of rotation, and a pair of washers being interposed between the two ends of the rotating cylindrical member and the first and second fixed cylindrical members, respectively. 7. Door hinge according to claim 1, characterized in that the plurality of first axial detents of the first detent wheel and the plurality of second axial detents of the second detent wheel have a configuration that corresponds to that of a conventional gear ( Fig. 5). 8. Door hinge according to claim 1, characterized in that when the plurality of first axial notches of the first raster wheel and the plurality of second axial notches of the second ratchet wheel are in engagement with one another, the rotation axis ( 114 ) in one direction, but not in the opposite direction can be rotated, when, when the axis of rotation is rotated by a tool introduced into the cover element ( 160 ) tool insertion groove in one direction, the torsion spring in the direction of its application a force to increase the torsional moment the same acts, while when the second ratchet wheel is shifted upward by lifting the first outward flange portion of the second cam member while overcoming the biasing force of the coil spring ( 150 ), the engagement between the first ratchet wheel and the second ratchet wheel is released and the torsion spring is bent, whereby their torsional moment is lost ingert. 9. Door hinge according to claim 1, characterized in that the part of larger diameter of the axis of rotation ( 114 ) is provided with a circumferential groove into which a pair of semi-circular washers ( 164 ) is inserted, which with a predetermined squeezing force by a screw ( 166 ) , which extends through the wall of the rotating cylindrical part of the first holding element ( 102 ) against the bottom surface of the circumferential groove. 10. Door hinge according to claim 9, characterized in that a friction-resistant and heat-resistant lining is attached to the inner peripheral surface of each semicircular washer ( 164 ). 11. Door hinge according to one of claims 1 or 8, characterized in that the one direction is the clockwise direction and the other direction is the counterclockwise direction, the torsion spring ( 120 ) is a left-hand torsion spring, when when the rotating cylindrical part NEN opening the door is rotated in the counterclockwise direction, a force acts on the torsion spring in its winding direction, as a result of which its torsional moment increases. 12. Door hinge ( 200 ) with:

• - A first holding element ( 202 ) which is to be fastened to a door and has a rotating cylindrical part ( 104 ), one end of which is closed;
• - a second support member ( 203 ) to be attached to a door frame and having a fixed cylindrical part ( 204 ) oriented vertically to the other end of the rotating cylindrical part of the first support member;
• - A rotation axis ( 114 ), one end of which is guided through the fixed cylindrical part of the second holding element into the rotating cylindrical part of the first holding element, so as to be rotatably held by the closed end of the rotating cylindrical part and a central section with a part of larger diameter becomes;
• - A torsion spring ( 120 ) which is wound in the rotating cylindrical part of the first holding element around the axis of rotation and one end of which is attached to the closed one end of the rotating cylindrical part, while its other end is attached to the larger diameter part of the rotary axis ;
• - A first ratchet wheel, which is housed in the fixed cylindrical part of the second holding element so that it can not rotate, it sits on the part of larger diameter of the axis of rotation and has a plurality of radially inwardly formed first axial notches;
• - A first cam element, which is inserted into the fixed cylindri's part of the second holding element so that it can not twist, it sits on the first Ras tenrad and has at least one axial Nockenvor jump ( 128 );
• - A second cam member having one end which is inserted into the fixed cylindrical part of the second holding member in such a manner that it can twist and move in the axial direction, the one end being provided with at least one axial cam recess ( 132 ) in which the axial cam projection can engage;
• - A second ratchet wheel, which is inserted into the second cam element in such a way that it can rotate integrally with the axis of rotation and can move in the axial direction, one end of which is provided with a plurality of second axial catches which engage with the several first axial notches of the first ratchet wheel can NEN;
• - A cover member ( 160 ) which is fixed at the other end of the axis of rotation, which extends through the first detent wheel, the first cam element, the second cam element and the second detent wheel; and
• - A coil spring ( 150 ) which is wound between the second Ras tenrad and the cover and the axis of rotation.

13. Door hinge according to claim 12, characterized in that the first and the second holding element ( 202 , 203 ) form a pair of horizontal holding elements which are arranged next to one another in the horizontal direction. 14. Door hinge ( 300 ) with:

• - A first holding element ( 324 ) which is to be fastened to a door and has a rotating cylindrical part, the central portion of which is closed in order to form two functional chambers ( 310 , 312 ) in it;
• - A second holding element ( 325 ) which is to be fastened to a door frame and has a pair of fixed cylindrical parts which are aligned vertically with the two ends of the rotating cylindrical part of the first holding element;
• - a first door hinge device ( 306 ) which is arranged in the first fixed cylindrical part of the second holding element and the first functional chamber of the rotating cylindrical part of the first holding element; and
• - A second door hinge device ( 308 ) which is arranged in the two fixed cylindrical part of the second holding element and the second functional chamber of the rotating cylindrical part of the first holding element.

15. Door hinge according to claim 14, characterized in that the first and the second door hinge device ( 306 , 308 ) are each provided with the following:

• - An axis of rotation ( 114 ), one end of which is inserted into the functional chamber of the rotating cylindrical part of the first holding member ( 324 ) through the fixed cylindrical part of the second holding member so as to pass through the closed central portion of the rotating cylindrical part and the is rotatably supported with a portion of larger diameter middle portion;
• - A torsion spring ( 120 ) which is wound in the functional chamber of the rotating cylindrical part of the first holding element around the axis of rotation and one end of which is attached to the closed central portion of the rotating cylindrical part, while the other end of the larger diameter part of the axis of rotation is attached;
• - A first ratchet wheel, which is inserted into the fixed cylindrical part of the second holding element in such a way that it cannot twist, being seated on the larger diameter part of the axis of rotation and having a plurality of radially inwardly formed first axial notches;
• - A first cam member which is inserted into the fixed cylindri's part of the second holding member so that it can not twist while sitting on the first Ras tenrad and has at least one axial cam projection ( 128 );
• - A second cam element, one end of which is inserted into the fixed cylindrical part of the second holding element in such a way that it can twist and move in the axial direction, one end being provided with at least one axial cam recess ( 132 ), in which the axial cam projection can engage;
• - A second ratchet wheel, which is used in the second Nockenele element that it can rotate integrally with the axis of rotation and move in the axial direction, one end of which is formed with a plurality of second axial catches which are connected to the plurality of first axial Detents of the first ratchet wheel can engage;
• - A cover member ( 160 ) which is fixed at the other end of the axis of rotation, which extends through the first detent wheel, the first cam element, the second cam element and the second detent wheel; and
• - A coil spring ( 150 ) which is wound between the second Ras tenrad and the cover around the axis of rotation.

16. Door hinge according to claim 14, characterized in that the first and the second door hinge device ( 306 , 308 ) are designed such that they lie in front of plane symmetry while they are centered on the central portion of the rotating cylindrical part, the torsional moments of the Torsion springs in the first and second door hinge device can be set independently. 17. Door hinge according to claim 15, characterized in that the torsion spring of the first door hinge device ( 306 ) and the torsion spring of the second door hinge device ( 308 ) are wound in the same direction, so that when the rotating cylindrical part is rotated by rotating a door which a torsion spring experiences a force acting in its winding direction, while the other torsion spring experiences a force acting in its bending direction, the one torsion spring which experiences a force acting in its winding direction has a greater torsional moment than the other torsion spring, which experiences a force in its opening direction, which means that opening and closing processes for a door can be carried out evenly. 18. Door hinge according to claim 14, characterized in that the central section has a fixed middle piece which is inserted into the rotating cylindrical part and is attached to this by a screw ( 166 ). 19. Door hinge according to claim 14, characterized in that the first and the second holding element ( 324 , 325 ) form a pair of vertical holding elements which are arranged side by side in the vertical direction. 20. Door hinge according to claim 14, characterized in that both in the first and the second door hinge device ( 306 , 308 ) the axis of rotation in one direction but not the other direction can be rotated when the plurality of first axial catches of the first Detent rads and the plurality of second axial detents of the second detent wheel are in mutual engagement, wherein when the axis of rotation is rotated in one direction by a tool inserted into the tool insertion groove formed in the cover element ( 160 ), a force in the winding direction of Torsion spring acts on this to increase their Tor sion moment, and when the second ratchet is pushed up by overcoming the preload force of the coil spring ( 150 ) by lifting the first outward flange portion of the second cam member, the engagement between the first ratchet and the second ratchet wheel is lifted and the torsion spring is bent, whereby its torsional moment decreases. 21. Door hinge according to one of claims 17 or 20, characterized in that the one direction is the clockwise direction and the other direction is the counterclockwise direction, the torsion springs of the first and the second door hinge device ( 306 , 308 ) being left-hand torsion springs , wherein when the associated door is opened, the rotating cylindrical part is rotated in the counterclockwise direction. 22. Door hinge according to claim 17 or 20, characterized in that the torsion spring of the first door hinge device ( 306 ) and the torsion spring of the second door hinge device ( 308 ) are wound in opposite directions, so that when the rotating cylindri's part by the twisting of the associated door is twisted, both torsion springs receive a force acting in the winding direction, whereby the torsional moment of both torsion springs is used to hold, open and close the door. 23. Door hinge according to claim 14, characterized in that the first and second holding element ( 402 , 403 ) form a pair of horizontal holding elements which are arranged next to one another in the horizontal direction, the second holding element being connected to the first fixed cylindrical part, which in turn is connected via a connector to the two fixed cylindrical part.