CN210858380U

CN210858380U - Window opener of mechanical linkage multi-point lock

Info

Publication number: CN210858380U
Application number: CN201921447330.XU
Authority: CN
Inventors: 苏卫华
Original assignee: Beijing Gc Opening Systems Intelligent Technology Co ltd
Current assignee: Beijing Gc Opening Systems Intelligent Technology Co ltd
Priority date: 2019-08-30
Filing date: 2019-08-30
Publication date: 2020-06-26
Anticipated expiration: 2029-08-30

Abstract

The utility model discloses a window opener of mechanical linkage multiple spot lock, including the shift fork that fixes on first screw and the push arm of one end installation on the second screw, first, second screw all overlap on same lead screw, the lead screw is fixed with the window frame, still fixed with the dog on the window frame, filled up with first spring between dog and first screw, be equipped with the ejector pad between first screw and second screw, still be equipped with one section optical axis on the lead screw to the transmission is connected with the motor on the lead screw; the other end of the push arm is provided with a sliding block which is arranged on the window sash in a sliding way, a first ejector block and a second ejector block which are arranged on two sides of the sliding block in a separated way are fixed on the window sash, and a second spring is padded between the sliding block and the second ejector block. The motor is arranged to drive the screw rod to simultaneously drive the first screw nut and the second screw nut to move, and the linkage structure is designed to realize corresponding sequential actions, so that the window opener is mechanically linked with the multipoint lock, the production and maintenance cost is greatly reduced, and the service life is effectively prolonged.

Description

Window opener of mechanical linkage multi-point lock

Technical Field

The utility model belongs to the technical field of the window, specifically say, in particular to ware of windowing of mechanical linkage multiple spot lock.

Background

At present, a casement window is a window with one side of a window sash hinged with a window frame by a hinge, has the characteristics of large opening angle and large ventilation volume, and is widely applied to various buildings. The traditional casement window is opened and closed by manually pushing and pulling, and the problems of inconvenient operation, large potential safety hazard, incapability of reliably locking and the like exist. Therefore, those skilled in the art have developed various electric window openers to open and close the casement window; the common electric window opener mainly comprises a push arm or a push arm assembly hinged between a window sash and a window frame, and the push arm is driven by a motor to swing or move so as to open and close the window sash. Various multi-point locks are designed to lock the closed casement window sash; the common multi-point lock mainly comprises a plurality of locking points and a pull plate for linking the locking points, wherein a locking nail is arranged on the pull plate, and the locking nail is shifted by utilizing a motor to drive a shifting fork, so that the multi-point lock can be electrically locked or unlocked.

When the window openers and the multipoint locks are used for opening windows, the multipoint locks need to be opened firstly, and then the window openers are used for opening windows; when the window is closed, the window opener is required to be used for closing the window, and then the multipoint lock is locked. The existing casement window is not provided with a corresponding mechanical structure to link the window opener and the multipoint lock in sequence, so that the window opener and the multipoint lock can only be respectively provided with motor drives, and sequential actions of the window opener and the multipoint lock are realized through a sequential module in a control program. Therefore, the arrangement of the two motors and the control module is not only unfavorable for the control of production and use cost, but also causes the complexity of the whole circuit structure of the window opener and the multipoint lock, the increase of fault points and the unfavorable guarantee of service life.

SUMMERY OF THE UTILITY MODEL

To the defect among the prior art, the utility model provides a ware of windowing of mechanical linkage multiple spot lock of low cost, low fault rate.

The above technical purpose of the present invention can be achieved by the following technical solutions: a window opener of a mechanical linkage multi-point lock comprises a shifting fork and a pushing arm, wherein the shifting fork is fixed on a first screw, one end of the pushing arm is installed on a second screw, the first screw and the second screw are both sleeved on the same screw rod, the screw rod is directly or relatively fixed with a window frame, a stop block is also directly or indirectly fixed on the window frame and is positioned on one side of the first screw, which is far away from the second screw, a first spring is padded between the stop block and the first screw, a pushing block is arranged between the first screw and the second screw, a section of optical axis is also arranged on the screw rod, and a motor is in transmission connection with the screw rod; the other end of the push arm is provided with a sliding block, the sliding block is slidably arranged on a window sash, a first ejector block and a second ejector block which are oppositely arranged are directly or indirectly fixed on the window sash, the sliding block slides between the first ejector block and the second ejector block, a second spring is arranged between the sliding block and the second ejector block in a cushioning mode, and when the window sash is in a closed state and the multipoint lock is in a locking state, a space is reserved between the sliding block and the first ejector block;

when the window sash is in a closed state and the multipoint lock is in a locked state, the motor is started to drive the screw rod to rotate, the first screw nut and the second screw nut move along the screw rod, the shifting fork shifts the multipoint lock locking nail to open the multipoint lock, in the process, the second screw nut drives the push arm and the slide block to move, the distance between the slide block and the first ejector block is reduced, and the window sash is still in the closed state; until the first screw nut moves to the optical axis of the screw rod and is disengaged from the screw rod, the motor continues to rotate, the first screw nut and the shifting fork stop moving, the second screw nut, the push arm and the sliding block continue to move, the sliding block is abutted against the first ejector block, and under the interaction of the push arm, the sliding block, the first ejector block and the window sash, the push arm moves and rotates to push the window sash open; when the window sash is closed from an opening state, the motor drives the screw rod to rotate reversely, the second screw nut moves along the screw rod, the push arm moves and rotates to pull back and close the window sash under the interaction of the second spring, the sliding block, the push arm and the window sash, in the process, the first screw nut cannot be meshed with the screw rod under the thrust action of the first spring and is still positioned at the optical axis, and the multipoint lock is in an opening state; and when the window sash is completely closed, the motor continues to rotate, the second screw and the push block push the first screw to be meshed with the screw rod, the first screw moves along the screw rod to drive the shifting fork to shift the multipoint lock locking nail to lock the window sash, and in the process, the second screw continues to move to drive the sliding block to compress the second spring.

By adopting the structure, the motor is designed to drive the screw rod to simultaneously drive the first screw nut and the second screw nut to move, and the optical axis is designed to remove the engagement between the first screw nut and the screw rod, so that the shifting fork stops moving after the multipoint lock is opened; the distance between the sliding block and the first top block is designed to prevent the window sash from being pushed in the opening process of the multipoint lock; a second spring is designed to realize that the sliding block is pulled by the push arm to close the window sash; the first spring is designed to prevent the window sash from being locked by the multi-point lock in the closing process; a push block is designed to realize that the first screw nut is meshed with the screw rod again to lock the multipoint lock after the window sash is closed; therefore, the window opener is mechanically linked with the multipoint lock, the integral mechanical and circuit structure of the window opener and the multipoint lock is greatly simplified, the production and maintenance cost is greatly reduced, and the service life is effectively prolonged.

The corresponding end of the push arm is mounted on the second nut through a first mounting piece, one end of the first mounting piece is fixed with the second nut, and the other end of the first mounting piece is hinged with the push arm; the corresponding end of the push arm is installed on the sliding block through a second installation piece and a connecting arm, one end of the second installation piece is fixed to the sliding block, the other end of the second installation piece is hinged to one end of the connecting arm, the other end of the connecting arm is hinged to the corresponding end of the push arm, and the connecting arm is shorter than the push arm. The push arm is simple in mounting structure, and the connecting arm is arranged to facilitate angle conversion of the push arm, so that window opening and closing actions are smoother.

The window frame is characterized by further comprising a strip-shaped shell, the stop block is fixed at one end of the shell, a seal head is fixed at the other end of the shell, the shell is directly or relatively fixed with the window frame, the lead screw, the motor, the first screw and the second screw are located in the shell, and strip-shaped notches corresponding to the shifting fork and the first mounting piece respectively are arranged on the shell. The screw rod and related parts are integrated and modularized, so that the internal parts are shielded and protected, and the service life is prolonged; and is convenient for integral installation and disassembly.

The window sash is further directly or indirectly fixed with a sliding groove, the first ejector block and the second ejector block are fixed at two ends of the sliding groove, the sliding block and the second spring are located in the sliding groove, and the sliding groove is provided with a strip-shaped notch corresponding to the second mounting piece. Like this with the integrated modularization of slider and relevant spare part, not only be favorable to shielding and protecting inside spare part, make things convenient for overall assembly and dismantlement moreover more.

Furthermore, a speed reducer is arranged between the output shaft of the motor and the screw rod, and the speed reducer is also positioned in the shell.

Preferably, the push block is sleeved on the screw rod in a tubular shape, and the push block is fixed with the second nut.

Preferably, the first spring is formed by a spiral spring, and the first spring is sleeved on the screw rod.

Preferably, a guide rod is connected between the first ejector block and the second ejector block, and the sliding block is sleeved on the guide rod; the second spring is composed of a spiral spring, and the second spring is sleeved on the guide rod.

Has the advantages that: the utility model discloses a set up a motor drive lead screw and drive first screw and second screw simultaneously and remove to design linkage structure and realize corresponding order action, thereby make ware and the mechanical linkage of multiple spot lock of windowing, not only greatly reduced production and maintenance cost, improved life moreover effectively, have characteristics such as think about ingenious, convenient to use.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below. Throughout the drawings, like elements or portions are generally identified by like reference numerals. In the drawings, elements or portions are not necessarily drawn to scale.

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a schematic view of the internal structure of fig. 1.

Fig. 3 is a schematic view of a matching structure of the screw rod, the first nut, the second nut and the push block.

Fig. 4 is a schematic view of an installation structure of the guide rod, the slider and the second spring.

Fig. 5 is a schematic view of the mounting structure of the first mounting piece.

Fig. 6 is a schematic view of the mounting structure of the second mounting piece.

Reference numerals: the device comprises a shifting fork 1, a push arm 2, a sliding groove 3, a second mounting piece 4, a shell 5, a connecting arm 6, a stop dog 7, a first spring 8, a first nut 9, a push block 10, a first mounting piece 11, a second nut 12, a screw rod 13, an optical axis 13a, a second ejector block 14, a second spring 15, a sliding block 16, a first ejector block 17, a motor 18, an end enclosure 19, a speed reducer 20 and a guide rod 21.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby.

It is to be noted that unless otherwise specified, technical or scientific terms used herein shall have the ordinary meaning as understood by those skilled in the art to which the present invention belongs.

As shown in fig. 1, fig. 2, fig. 3, and fig. 6, the present embodiment provides a window opener with a mechanical linkage multi-point lock, which includes a shifting fork 1 for shifting a lock pin of the multi-point lock and a pushing arm 2 for pushing a casement window sash, where the structures of the multi-point lock and the casement window are the prior art and are not described herein. The shifting fork 1 is fixed on a first screw nut 9, one end of the pushing arm 2 is installed on a second screw nut 12, and the first screw nut 9 and the second screw nut 12 are both sleeved on the same screw rod 13. Specifically, the method comprises the following steps: the corresponding end of the push arm 2 is installed on a second screw nut 12 through a horizontal first installation piece 11, one end of the first installation piece 11 is fixed with the second screw nut 12, and the other end of the first installation piece is hinged with the push arm 2. The screw rod 13 is directly or relatively fixed with the window frame, a stop 7 is also directly or indirectly fixed on the window frame, the stop 7 is positioned on one side of the first screw 9, which is far away from the second screw 12, and a first spring 8 is padded between the stop 7 and the first screw 9. In this embodiment, the first spring 8 is preferably formed by a coil spring, and the first spring 8 is sleeved on the screw rod 13. A push block 10 is arranged between the first nut 9 and the second nut 12, the shape of the push block 10 is not limited, in this embodiment, it is preferable that the push block 10 is sleeved on the screw rod 13 in a tubular shape, and the push block 10 is fixed with the second nut 12. The screw rod 13 is further provided with a section of optical axis 13a, and the screw rod 13 is in transmission connection with a motor 18. More specifically: a reducer 20 is installed between the output shaft of the motor 18 and the screw 13.

As shown in fig. 1, 2, 4 and 5, a slider 16 is mounted at the other end of the push arm 2, specifically: the corresponding end of the push arm 2 is installed on the sliding block 16 through a second installation piece 4 and a connecting arm 6, one end of the second installation piece 4 is fixed with the sliding block 16, the other end of the second installation piece 4 is hinged with one end of the connecting arm 6, the other end of the connecting arm 6 is hinged with the corresponding end of the push arm 2, and the connecting arm 6 is shorter than the push arm 2. The sliding block 16 is slidably mounted on a window sash, a first top block 17 and a second top block 14 which are oppositely arranged are directly or indirectly fixed on the window sash, the sliding block 16 slides between the first top block 17 and the second top block 14, and a second spring 15 is padded between the sliding block 16 and the second top block 14. In this embodiment, preferably, a guide rod 21 is connected between the first top block 17 and the second top block 14, and the sliding block 16 is sleeved on the guide rod 21; the second spring 15 is formed of a coil spring, and the second spring 15 is fitted over the guide rod 21. When the sash is closed and the multipoint lock is locked, there is a space between the slider 16 and the first top piece 17.

As shown in fig. 1, 3, 4, 5 and 6, the present embodiment further includes an elongated housing 5, the stopper 7 is fixed to one end of the housing 5, and a sealing head 19 is fixed to the other end of the housing 5. The bottom surface of the shell 5 is directly or relatively fixed with a window frame, the screw rod 13, the motor 18, the first screw 9, the second screw 12 and the speed reducer 20 are all located in the shell 5, and bar-shaped notches corresponding to the shifting fork 1 and the first mounting piece 11 are formed in the shell 5. The window sash is further directly or indirectly fixed with a sliding groove 3, the first top block 17 and the second top block 14 are fixed at two ends of the sliding groove 3, the sliding block 16, the second spring 15 and the guide rod 21 are all located in the sliding groove 3, and the sliding groove 3 is provided with a strip-shaped notch corresponding to the second mounting piece 4. The side of the sliding groove 3 facing away from the second mounting piece 4 faces the sash.

The working principle of the embodiment is as follows:

when the window sash is in a closed state and the multipoint lock is in a locked state, the motor 18 is started to drive the screw rod 13 to rotate, the first screw nut 9 and the second screw nut 12 move along the screw rod 13, the shifting fork 1 shifts the multipoint lock locking nail to open the multipoint lock, in the process, the second screw nut 12 drives the push arm 2 and the sliding block 16 to move, the distance between the sliding block 16 and the first ejector block 17 is reduced, and the window sash is still in the closed state; until the first screw 9 moves to the optical axis 13a of the screw 13 to be separated from the engagement with the screw 13, the motor 18 continues to rotate, the first screw 9 and the shifting fork 1 stop moving, the second screw 12, the push arm 2 and the slide block 16 continue to move, the slide block 16 is abutted against the first ejector block 17, and under the interaction of the push arm 2, the slide block 16, the first ejector block 17 and the window sash, the push arm 2 moves and rotates so as to push the window sash open;

when the window sash is closed from an opening state, the motor 18 drives the screw rod 13 to rotate reversely, the second screw 12 moves along the screw rod 13, the push arm 2 moves and rotates to pull the window sash back to be closed under the interaction of the second spring 15, the sliding block 16, the push arm 2 and the window sash, in the process, the first screw 9 cannot be meshed with the screw rod 13 under the thrust action of the first spring 8 and is still positioned at the optical axis 13a, and the multipoint lock is in an opening state; and after the window sash is completely closed, the motor 18 continues to rotate, the second screw 12 and the push block 10 push the first screw 9 to be meshed with the screw rod 13, the first screw 9 moves along the screw rod 13 to drive the shifting fork 1 to shift the multipoint lock pin to lock the window sash, and in the process, the second screw 12 continues to move to drive the sliding block 16 to compress the second spring 15.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the scope of the embodiments of the present invention, and are intended to be covered by the claims and the specification.

Claims

1. The utility model provides a ware of windowing of mechanical linkage multiple spot lock, includes shift fork and push arm, characterized by: the shifting fork is fixed on a first nut, one end of the pushing arm is installed on a second nut, the first nut and the second nut are sleeved on the same screw rod, the screw rod is directly or relatively fixed with a window frame, a stop block is also directly or indirectly fixed on the window frame and positioned on one side of the first nut, which is far away from the second nut, a first spring is padded between the stop block and the first nut, a pushing block is arranged between the first nut and the second nut, a section of optical axis is also arranged on the screw rod, and the screw rod is in transmission connection with a motor; the other end of the push arm is provided with a sliding block, the sliding block is slidably arranged on a window sash, a first ejector block and a second ejector block which are oppositely arranged are directly or indirectly fixed on the window sash, the sliding block slides between the first ejector block and the second ejector block, a second spring is arranged between the sliding block and the second ejector block in a cushioning mode, and when the window sash is in a closed state and the multipoint lock is in a locking state, a space is reserved between the sliding block and the first ejector block;

when the window sash is in a closed state and the multipoint lock is in a locked state, the motor is started to drive the screw rod to rotate, the first screw nut and the second screw nut move along the screw rod, the shifting fork shifts the multipoint lock locking nail to open the multipoint lock, in the process, the second screw nut drives the push arm and the slide block to move, the distance between the slide block and the first ejector block is reduced, and the window sash is still in the closed state; until the first screw nut moves to the optical axis of the screw rod and is disengaged from the screw rod, the motor continues to rotate, the first screw nut and the shifting fork stop moving, the second screw nut, the push arm and the sliding block continue to move, the sliding block is abutted against the first ejector block, and under the interaction of the push arm, the sliding block, the first ejector block and the window sash, the push arm moves and rotates to push the window sash open;

when the window sash is closed from an opening state, the motor drives the screw rod to rotate reversely, the second screw nut moves along the screw rod, the push arm moves and rotates to pull back and close the window sash under the interaction of the second spring, the sliding block, the push arm and the window sash, in the process, the first screw nut cannot be meshed with the screw rod under the thrust action of the first spring and is still positioned at the optical axis, and the multipoint lock is in an opening state; and when the window sash is completely closed, the motor continues to rotate, the second screw and the push block push the first screw to be meshed with the screw rod, the first screw moves along the screw rod to drive the shifting fork to shift the multipoint lock locking nail to lock the window sash, and in the process, the second screw continues to move to drive the sliding block to compress the second spring.

2. The window opener of mechanical linkage multipoint lock of claim 1, wherein: the corresponding end of the push arm is mounted on the second nut through a first mounting piece, one end of the first mounting piece is fixed with the second nut, and the other end of the first mounting piece is hinged with the push arm; the corresponding end of the push arm is installed on the sliding block through a second installation piece and a connecting arm, one end of the second installation piece is fixed to the sliding block, the other end of the second installation piece is hinged to one end of the connecting arm, the other end of the connecting arm is hinged to the corresponding end of the push arm, and the connecting arm is shorter than the push arm.

3. The window opener of the mechanical linkage multipoint lock of claim 2, wherein: the window frame is characterized by further comprising a strip-shaped shell, the stop block is fixed at one end of the shell, a seal head is fixed at the other end of the shell, the shell is directly or relatively fixed with the window frame, the lead screw, the motor, the first screw and the second screw are located in the shell, and strip-shaped notches corresponding to the shifting fork and the first mounting piece respectively are arranged on the shell.

4. The window opener of mechanical linkage multipoint lock of claim 3, wherein: the window sash is further directly or indirectly fixed with a sliding groove, the first ejector block and the second ejector block are fixed at two ends of the sliding groove, the sliding block and the second spring are located in the sliding groove, and the sliding groove is provided with a strip-shaped notch corresponding to the second mounting piece.

5. The window opener of mechanical linkage multipoint lock of claim 3 or 4, wherein: and a speed reducer is arranged between the motor output shaft and the screw rod, and the speed reducer is also positioned in the shell.

6. The window opener of mechanical linkage multipoint lock of claim 1, wherein: the push block is sleeved on the screw rod in a tubular shape, and the push block is fixed with the second nut.

7. The window opener of mechanical linkage multipoint lock of claim 1, wherein: the first spring is composed of a spiral spring, and the first spring is sleeved on the screw rod.

8. The window opener of mechanical linkage multipoint lock of claim 1, wherein: a guide rod is connected between the first ejector block and the second ejector block, and the sliding block is sleeved on the guide rod; the second spring is composed of a spiral spring, and the second spring is sleeved on the guide rod.