DE4445392A1 - Automatic closing device for doors and windows - Google Patents

Abstract

The energy accumulator which is charged as the door is opened is a pneumatic accumulator (16) associated with a piston-cylinder unit (25). The cylinder unit (9) has several work chambers (33,34). The piston unit (11) has several active piston faces (13,15). The piston has different sized active piston faces. Three active surfaces of different size can be provided which become active in different sequence during opening and closing. The work chambers of the cylinder unit are associated with the active piston faces. The piston unit can have a stepped piston interacting with a stepped cylinder (9).

Description

The invention is based on a preferred shown in the drawing Exemplary embodiment explained. It shows:

Fig. 1 is a schematic view of a pneumatic door closer in a closed position,

Fig. 2 is a schematic view of a pneumatic door closer when opening a door and

Fig. 3 is a schematic view of a pneumatic door closer when closing a door.

Fig. 1 shows a schematic representation with a door closer 1 , which is connected via a control mechanism 2 or a linkage with a door 3 in United. The actuating mechanism 2 has a suitable transmission 5 which converts the pivoting movement of the door 3 into a linear movement during the opening and closing of the door 3 and the door closer 1 is actuated via a pressure-pull rod and piston rod 6, which when opening the door 3 in The direction of the arrow 4 performs an opening movement 7 ( FIG. 2) and when the door 3 closes (against the direction of the arrow 4 ) a closing movement 8 ( FIG. 3).

The door closer 1 is designed as a pneumatic door closer and has a piston-cylinder unit 25 with a cylinder 9 and a piston 11 , the piston 11 being shown in a closed end position 31 in FIG. 1. The piston 11, which is movable in the opening and closing movement 7 , 8 via the piston rod 6, is arranged in the cylinder 9 . The piston 11 is designed as a stepped piston which has a first piston section 12 with a smaller cross section and a second piston section 14 with a larger cross section. On the left end face of the stepped piston in FIG. 1, a circular cross-sectional piston surface 13 is formed on the piston section 12 and a larger annular piston surface 15 on the piston section 14 .

Arranged in the cylinder 9 is a pressure vessel 16 designed as an energy store, which can hold the air compressed by the piston 11 when the door 3 is opened into the cylinder 9 . This pressure vessel 16 lies against the inner wall of the cylinder 9 and forms a stepped cylinder which is matched to the stepped piston. Due to its annular configuration, the pressure vessel 16 has a cylindrical recess 20 . This is adapted to the diameter of the first piston section 12 of the stepped piston 11 with a cross-sectional area that corresponds to the piston surface 13 . The length of the pressure vessel 16 or cylinder 20 corresponds to the axial length of the first piston section 12 , so that in an open end position 32 (shown in dashed lines in FIG. 2) the first piston portion 12 can be fully inserted into the pressure vessel 16 or into the cylinder 20 . Of the piston portion 14 receiving cylinder interior is adapted in cross-section the piston section fourteenth

The stepped piston 11 is axially displaceably guided in the stepped cylinder. Depending on the position of the piston 11, a step-shaped working space ( FIG. 1) or two working spaces 33 , 34 ( FIGS. 2, 3) are or are formed in the interior of the stepped cylinder. The effective piston surface, which is formed from the surfaces 13 and 15 , is assigned to the step-shaped working space ( FIG. 1). The effective piston surfaces 15 and 13 are assigned to the working spaces 33 , 34 ( FIGS. 2, 3).

A closing spring 38 can advantageously be arranged between the pressure vessel 16 and the annular piston surface 15 of the piston 11 . This can be designed as a compression spring and holds the piston 11 under pressure in the closed position 31 shown in FIG. 1. The door 3 can not open by itself, for. B. by a gust of wind, and leads the piston 9 after opening the door 3 by a person with certainty by the tension of the at least partially biased closing spring 38 in the closed position 31 .

A control valve 18 is arranged in the pressure vessel 16 . The control valve 18 is pneumatically controlled by the piston 11 . The control depends on the position of the piston 11 . The control valve 18 serves to connect the working spaces 33 , 34 to the pressure vessel 16 or to the environment in the various operating positions of the piston 11 .

The control valve 18 has a control piston 22 which is guided in a control cylinder 22 b slidably tight. The control cylinder 22 b is connected to a tube 19 which opens into the cylinder space 10 in the region of the working space 33 . The control cylinder 22 b and the tube 19 extend axially parallel to the cylinder 9 . Opposite the tube 19 , the control valve 18 has a resetting element 21 designed as a spring, which holds the control piston 22 of the control valve 18 in an initial position 23 , in which the tube 19 is closed.

The control cylinder 22 b is connected at the end having the spring 21 to the pressure vessel 16 , so that the spring-loaded side of the control piston 22 in the figure always receives the pressure that prevails in the pressure vessel 16 .

The control piston 22 has a through bore 24 arranged in the control piston 22 essentially transversely to the direction of movement, which in the starting position 23 ( FIG. 1) and in an operating position when closing ( FIG. 3) via a first bore in the control cylinder 22 b the cylinder interior 10 or the sub-space 34 connects to the pressure vessel 16 and in an operating position when opening ( FIG. 2) connects the sub-space 34 to the environment via a second bore in the control cylinder 22 b with outlet 37 . In this operating position when opening ( FIG. 2), the working space 33 is connected to the pressure vessel 16 .

A vacuum valve 27 is also arranged on the cylinder 9 . It has an adjusting device 28 , by means of which the opening force of a valve tappet can be adjusted, so that depending on the vacuum occurring in the cylinder 9 during a piston movement in the closing movement 8 , the vacuum valve 27 can open more or less quickly. The vacuum valve 27 is arranged in the cylinder space 10 in the region of the larger cross section adjacent to the pressure vessel 16 .

On the cylinder 9 , a ventilation opening 29 is also provided, which interacts directly with the cylinder interior 10 and connects the cylinder interior 10 to the environment only in a closed position 31 of the piston 11 , so that pressure compensation takes place in the cylinder interior 10 and ambient pressure can also prevail. The ventilation opening 29 is also arranged in the cylinder space 10 in the region of the larger cross section, and at a distance from the vacuum valve 27 away from the pressure vessel 16 .

The functioning of the pneumatic door closer when opening and closing a door is explained below with reference to FIGS . 1 to 3:

When the door 3 is closed, as shown in FIG. 1, the piston 11 is in the closed end position 31 in the cylinder 9 . When opening the door 3 in the direction of the arrow 4 , the gear 5 is actuated and converts the pivoting movement of the door 3 into a linear movement which is transmitted directly to the piston 11 by the push-pull rod 6 . The piston 11 is inserted into the cylinder 9 in the opening movement 7 . Immediately after the opening movement begins, the piston 11 closes the vent opening 29 with its second piston section 14 guided on the inner wall of the cylinder, so that a stepped cylinder interior 10 is closed. When the piston 11 is pushed in further, the air in the cylinder interior 10 is compressed. The large piston surface of the stepped piston acts, which is composed of the piston surfaces 13 and 15 . The pressure vessel 16 is acted upon by the pressure in the cylinder interior 10 through the bore 24 in the control piston 22 . As soon as the first piston section 12 is inserted into the cylinder 20 in the pressure vessel 7 , the interior of the cylinder 10 is divided into a right partial volume 33 with the partial pressure p 1 and a left partial volume 34 with the partial pressure p 2 ( FIG. 2).

If the piston 1 1 is pushed further into the opening movement 7 , as shown in FIG. 2, the pressure p 1 in the right partial volume 33 increases faster than the pressure p 2 in the left partial volume 34 . The prevailing in the right part volume 33 pressure p₁ acts through the tube 19 on the control valve 18 and the control piston 22 is transferred against the restoring force of the spring 21 in a rear position 36 . In this rear position 36 of the control piston 22 , the pressure vessel 16 is charged with the pressure p 1, ie the air present in the right partial volume 33 is compressed and pressed into the pressure vessel 16 . The effective piston surface is the medium-sized annular piston surface 15 . The air present in the left partial volume 34 escapes into the environment via an outlet 37 , since in the rear position 36 the control piston 22 connects the outlet 37 and the left partial volume 34 by means of the through bore 24 .

Immediately before the door 3 is fully opened and the piston 11 is pushed into the opening position 32 , the first piston section 12 closes the outlet 37 or the passage opening 24 , so that no more air can escape from the left partial volume 34 . The remaining air in this left-hand partial volume 34 is now compressed and causes the door 3 to be damped immediately before the opening position 32 (shown in broken lines) is reached completely. In addition, the lock of 38 can support this. The degree of possible damping can thus also be determined by the distance between a rear cylinder wall and the through bore 24 .

The closing process takes place under the effect of the pneumatic pressure in the pressure container 16 as follows:

Immediately after the piston 11 no longer experiences an opening movement 7 or is no longer acted upon in the opening direction, there is no longer any excess pressure on the control piston 22 . The spring 21 presses the control piston 22 back into the starting position 23 and closes the bore 19 . As a result, the air compressed and stored in the pressure vessel 16 can flow into the cylinder space 34 via the through bore 24 . The piston 11 is moved to the right in the closing direction 8 in FIG. 3. The small piston surface 13 acts. The right cylinder chamber 33 is no longer in communication with the pressure vessel 16 . The closing movement 8 causes a negative pressure in the right cylinder chamber 33 , which can be compensated for by the negative pressure valve 27 . About the setting of the adjusting device 28 of the vacuum valve 27 , a more or less large vacuum can be generated, which in turn can have an influence on the closing speed of the door 3 . This negative pressure in the right partial volume 33 can partially counteract the excess pressure of the left partial volume 34 from the pressure container 16 .

When the door 3 is closed, in this first phase, in which the first piston 12 is moved within the cylinder in the pressure vessel 16 , less pressure is released via the same piston travel than when the door 3 is opened in the pressure vessel 16 in this phase or was compressed. The piston surface 13 that is effective when closing in this opening angle range of the door is smaller than the ring piston surface 15 that is effective in this region when opening.

After the first piston 12 emerges from the cylinder 20 of the pressure vessel 16 , the right and left partial volumes 33 , 34 are combined to form a common volume and the relatively high, residual pressure prevailing in the pressure vessel 16 due to the changeover of the control valve 18 after the opening movement of the large annular piston surface 15 on the small piston surface 13 was achieved, can act on the entire piston surface 13 , 15 of the piston 11 , so that the door 3 can be pressed with increased force into the lock. At the same time, the closing spring 38 can act un supportive. The vacuum valve 27 is closed immediately after the first piston 12 has emerged from the cylinder 20 of the pressure container 16 , since the pressure in the left cylinder chamber 34 spreads to the entire cylinder interior 10 .

As soon as the door 3 is completely closed, as shown in FIG. 1, the piston 11 is again in the closed end position 31 and can be kept under pressure in this closed end position 31 by the closing spring 38 , since the closing spring 38 in the closed end position 31 can still be arranged at least slightly before excited. Pressure equalization with the surroundings can take place in the cylinder interior 10 via the vent opening 29 . This has the advantage that when a reopening of the door 3, the piston 11 compresses the prevailing in-cylinder space 10 and the ambient pressure does not have to work against a possibly still in the cylinder space 10 verblei reproduced residual pressure.

The characteristic of the door closer has a path-force curve, which at Opening and closing is different, with the closing force immediately before the door is pressed into the lock, is the largest and at Opening a relatively low opening resistance at small opening angles occurs. The door closer works with a pneumatic pressure accumulator Lift mechanism which, when opened manually, requires manual effort is loaded when opening and then the door closes automatically. It is not External compressed air supply required to generate the pneumatic pressure.  

Furthermore, no closer spring is required. An additional arrangement of a closer spring 38 , however, has the advantage that the door 3 is held securely in the closed end position and the closing movement is supported.

A door closer 1 is thus created which, due to the small number of mechanical moving parts, has a structurally simple structure and is inexpensive. In addition, this can be operated without lubricants by the piston 11 and / or the cylinder 9 having suitable sliding or guide surfaces, so that a considerable expansion of the area of application can be achieved.

Alternatively, a door closer 1 can also be provided, in which the pressure vessel 16 is arranged outside the cylinder interior 10 , the step-like configuration of the cylinder interior 10 being able to be achieved by simple design measures. The in-cylinder space 10 can also be connected via air hoses to the pressure vessel 16, so that the pressure vessel can be arranged separately 16 from the cylinder space 10th

It is understood that in the transmission of the pivotal movement of the door 3 in a linear movement of the piston 11 also a known lever mechanism other type or other known implementation mechanisms can be used.

Claims (18)

1. Drive for closing a wing of a door or window, preferably a door closer,
with an energy store for closing the wing, the energy store being loaded when the wing is opened and being discharged when the wing is closed,
it is preferably provided that the opening of the wing takes place with manual effort and the energy store is loaded by the manual effort and the closing of the wing takes place automatically under the action of the force store, the force store being discharged,
characterized in that the energy accumulator ( 16 ) is designed as a pneumatic accumulator. 2. Drive according to claim 1, characterized in that a piston-cylinder device ( 25 ) is provided which cooperates with the energy accumulator ( 16 ). 3. Drive according to claim 2, characterized in that the cylinder device ( 9 ) has a plurality of work spaces ( 33 , 34 ), preferably in a cylinder ( 9 ) a plurality of work spaces ( 33 , 34 ) are formed. 4. Drive according to claim 2 or 3, characterized in that the piston device ( 11 ) has a plurality of effective piston surfaces ( 13 , 15 ), preferably a piston ( 11 ) has a plurality of effective piston surfaces ( 13 , 15 ). 5. Drive according to claim 4, characterized in that the piston ( 11 ) different effective piston areas ( 13 , 15 ) and that it is preferably provided that in a certain opening angle range when opening a first piston surface ( 15 ) and when closing a second piston surface ( 13 , 13 + 15 ) is effective in this opening angle range, the size of the first piston surface ( 15 ) being not equal to the size of the second piston surface ( 13 ). 6. Drive according to claim 5, characterized in that three differently sized effective piston surfaces ( 13 , 15 , 13 + 15 ) are provided, which are effective in different orders when opening and closing. 7. Drive according to one of claims 3 to 6, characterized in that the working spaces ( 33 , 34 ) of the cylinder device are assigned to the effective piston surfaces ( 13 , 15 , 13 + 15 ). 8. Drive according to one of claims 2 to 7, characterized in that the piston device has a stepped piston ( 11 ) which cooperates with a stepped cylinder ( 9 ). 9. Drive according to one of the preceding claims, characterized in that a control valve ( 18 ) is provided, which cooperates with the energy accumulator ( 16 ). 10. Drive according to claim 9, characterized in that the control valve interacts with a piston-cylinder device ( 25 ) connected to the energy accumulator ( 16 ), preferably from the piston position of the piston-cylinder device ( 25 ) can be controlled. 11. Drive according to one of the preceding claims, characterized in that the energy accumulator ( 16 ) is arranged in a cylinder interior ( 10 ) and is annular. 12. Drive according to claim 11, characterized in that the piston ( 11 ) is at least partially insertable into a recess ( 20 ) of the energy accumulator ( 16 ) formed by the annular configuration. 13. Drive according to claim 11 or 12, characterized in that when opening the door ( 3 ) of the piston ( 11 ) in the recess ( 20 ) of the energy accumulator ( 16 ) and a first and a second partial volume ( 33 , 34th ) forms. 14. Drive according to one of claims 11 to 13, characterized in that when the piston ( 11 ) enters the recess ( 20 ) of the energy accumulator ( 16 ), the control valve ( 18 ) from an initial position ( 23 ) to a rear position ( 36 ) can be positioned. 15. Drive according to one of claims 11 to 14, characterized in that the energy accumulator ( 16 ) with the first partial volume ( 33 ) is charged and the second partial volume ( 34 ) escapes from the cylinder ( 9 ) via an outlet ( 37 ) . 16. Drive according to one of claims 11 to 15, characterized in that when the door ( 3 ) closes, the control valve ( 18 ) blocks the air outlet from the energy accumulator ( 16 ) into the first partial volume ( 33 ) and into the second partial volume ( 34 ) releases. 17. Drive according to one of claims 11 to 16, characterized in that when closing the door ( 3 ), the vacuum valve ( 27 ) cooperates with the first partial volume ( 33 ). 18. Drive according to one of claims according to 17, characterized in that the vacuum valve ( 27 ) with an adjusting device ( 28 ) is adjustable.