CN111720006B - Automatic wash ash removal window - Google Patents

Abstract

The invention belongs to the technical field of windows, and particularly discloses an automatic cleaning and dust removing window which comprises a window main body and a sliding chute, wherein the window main body is connected to the sliding chute in a sliding manner, a vertical second guide hole is formed in the side wall of the window main body, a second shaft rod is connected in the second guide hole in a sliding manner, the axial direction of the second shaft rod is perpendicular to the second guide hole, a cleaning wheel is rotatably connected to the end part of the second shaft rod, and the outer wall of the cleaning wheel abuts against the inner surface of the sliding chute. The invention aims to provide an automatic cleaning and dust removing window, which aims to solve the problem that the sliding chute of a push-pull window is difficult to clean.

Description

Automatic wash ash removal window

Technical Field

The invention belongs to the technical field of windows, and particularly discloses an automatic cleaning and dust removing window.

Background

The window is one of essential components in building decoration, and can play a role in ventilation, illumination improvement and warm keeping and temperature control; the window is divided into a plurality of types according to the opening and closing mode, such as a casement window, a sliding window and the like.

In the sliding window in the prior art, the window body is generally freely pushed and pulled and slides in the sliding groove. When cleaning at ordinary times, the inner space of the sliding chute is narrow, so that the cleaning of the sliding chute is troublesome and difficult to clean.

Disclosure of Invention

The invention aims to provide an automatic cleaning and dust removing window, which aims to solve the problem that the sliding chute of a push-pull window is difficult to clean.

In order to achieve the purpose, the basic scheme of the invention is as follows: the utility model provides an automatic wash ash removal window, includes window main part and spout, window main part sliding connection is on the spout, and window main part lateral wall opens has vertical second guiding hole, and sliding connection has the second axostylus axostyle in the second guiding hole, and second axostylus axostyle axial perpendicular to second guiding hole, second axostylus axostyle tip rotate and are connected with the cleaning wheel, and the inner surface at the spout is held up in the cleaning wheel outer wall.

The working principle and the beneficial effects of the basic scheme are as follows:

1. this technical scheme is through the cleaning wheel of rotating the connection at the lateral wall of window main part to the realization cleans the internal surface of spout. When people are in the push-and-pull process in daily life, the cleaning wheels can roll in the sliding grooves in a reciprocating mode, dust in the sliding grooves is concentrated on the left side and the right side, the dust is convenient to concentrate and recycle, and the technical effect of effectively cleaning the sliding grooves is achieved.

2. This technical scheme sets up the second guiding hole at the window main part lateral wall to realize that the cleaning wheel passes through the second axostylus axostyle and freely slides along vertical direction in the second guiding hole. An operator can select to manually lift the cleaning wheel when the window main body moves to one side according to actual needs, the specific lifting mode is that the cleaning wheel is held by hand to lift, so that the cleaning wheel leaves the chute, and when the window main body moves to the other side, the cleaning wheel is selected to be put down, so that the cleaning wheel falls into the chute to clean. The structure can realize the one-way cleaning of the cleaning wheel, so that the dust in the chute is only concentrated on one side, and the dust can be conveniently and subsequently collected.

Furthermore, a supporting sliding rail is fixed on the top surface of the sliding groove and parallel to the sliding groove, and the window main body slides on the supporting sliding rail.

Has the advantages that: this technical scheme is through addding the effect that supports the slide rail in order realizing the window main part direction.

Further, a first rack is fixed on the top of the supporting slide rail, a first guide hole is horizontally formed in the side wall of the window body, a first shaft lever is connected in the first guide hole in a sliding mode and parallel to a second shaft lever, a gear is rotatably connected to the end portion of the first shaft lever and meshed with the first rack, and a vertical second rack is fixedly connected to the side wall of the second shaft lever; the gear can engage the second rack when the first guide hole is located at a side close to the second shaft.

Has the beneficial effects that: when the window main body continues to move towards the second shaft rod, the inner wall of the first guide hole can abut against the outer wall of the first shaft rod and drive the first shaft rod to horizontally move together. Because the gear on the primary shaft pole and the first rack on the support slide rail are intermeshing all the time, the gear can and second rack intermeshing, therefore the gear can take place circumferential direction under the meshing of first rack, and the gear also drives the cooperation and also drives the vertical upward movement of second rack at the second guiding hole simultaneously, also drives the wheel of cleaning and rises simultaneously, finally realizes that the wheel of cleaning leaves the spout. When the window main body moves in the opposite direction, the cleaning wheel falls into the chute under the action of gravity. According to the technical scheme, the mechanical mechanism is matched, and the automatic control of one-way cleaning of the cleaning wheel is realized.

Further, the inner walls of the two ends of the first guide hole are arc chamfers.

Has the advantages that: this technical scheme is through adopting the structure of both ends circular arc chamfer to guarantee that first axostylus axostyle can make free circumference roll in first guiding hole in the counterbalance.

Furthermore, the bottom surface of the sliding groove is provided with a collecting hole, a cavity is arranged below the collecting hole, and the cavity is communicated with the collecting hole.

Has the advantages that: this technical scheme is through seting up the collection hole in the bottom surface of spout to concentrate the recovery to the dust, avoid the dust to expose externally.

Furthermore, the side wall of the window body is communicated with the cavity, and a dust collection drawer is connected in the cavity in a sliding manner.

Has the advantages that: this technical scheme is through sliding collection dirt drawer in the cavity to clear away the dust of gathering.

Furthermore, a supporting rod is fixedly connected between the second rack and the second shaft rod.

Has the advantages that: this technical scheme utilizes branch to realize the fixed connection of second rack and second axostylus axostyle, improves joint strength between the two.

Further, the window main body comprises a frame, and a glass plate is embedded and fixed in the frame.

Has the advantages that: this technical scheme is through specifically injecing the frame to the window main part can freely slide.

Further, the frame is of a rectangular structure.

Has the advantages that: this technical scheme is through the frame that adopts the rectangle structure to can freely slide in the spout horizontally.

Furthermore, the outer wall of the cleaning wheel is fixedly connected with a plurality of cleaning cloth strips.

Has the advantages that: this technical scheme cleans the cloth strip through addding to the realization improves the clean degree that cleans the wheel pair spout and cleans.

Drawings

Fig. 1 is a schematic front view of an automatic cleaning and dust removing window according to a first embodiment of the present invention; (ii) a

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is a partial cross-sectional side view of a self-cleaning ash removal window according to a first embodiment of the present invention;

fig. 4 is a schematic front view of an automatic cleaning and dust removing window according to a second embodiment of the present invention.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: the window comprises a window body 1, a frame 2, a first chute 3, a second chute 4, a supporting slide rail 5, a collecting hole 6, a cavity 7, a dust collection drawer 8, a frame 9, a cleaning wheel 10, a first guide hole 11, a second guide hole 12, a first shaft rod 13, a second shaft rod 14, a first rack 15, a second rack 16, a gear 17 and a support rod 18.

The examples are essentially as follows: as shown in fig. 1, the automatic cleaning and dust removing window comprises two window bodies 1 and a frame 2. The top of the frame 2 is provided with an upper chute group, and the bottom of the frame 2 is provided with a lower chute group. The upper chute group and the lower chute group have the same size and structure.

As shown in fig. 3, the lower chute group includes a first chute 3 and a second chute 4 which are parallel to each other, a supporting slide rail 5 is integrally formed on the bottom surfaces of the first chute 3 and the second chute 4, the supporting slide rail 5 is integrally formed with the first chute 3 and the second chute 4, and the supporting slide rail 5 is parallel to the lower chute group.

The two window bodies 1 are respectively connected to the first sliding chute 3 and the second sliding chute 4 in a sliding manner. The window main body 1 comprises a rectangular frame 9, a glass plate is embedded and fixed on the frame 9, and the frames 9 of the two window main bodies 1 are respectively connected on the first sliding chute 3 and the second sliding chute 4 in a sliding manner.

As shown in fig. 2, a first rack 15 is fixedly connected to the top surface of the supporting slide rail 5, and a first guide hole 11 is formed in the side wall of the lower frame 9, and the first guide hole 11 is parallel to the horizontal direction. A first shaft rod 13 is slidably connected in the first guide hole 11, and the axial direction of the first shaft rod 13 is perpendicular to the first guide hole 11. The first shaft 13 is coaxially and rotatably connected with a gear 17. The gear 17 engages on the first rack 15 supporting the slide 5. The inner walls of the left end and the right end of the first guide hole 11 are both in arc transition, and the radius of the arc transition is equal to the radius of the outer wall of the first shaft rod 13.

The frame 9 is provided with a second guide hole 12 on the right side of the first guide hole 11, the second guide hole 12 is parallel to the vertical direction, and the upper end and the lower end of the second guide hole 12 are both closed. A second shaft 14 is slidably connected in the second guide hole 12, and the axial direction of the second shaft 14 is parallel to the axial direction of the first shaft 13. Both ends of the second shaft lever 14 extend outwards outside the frame 2, and both ends of the second shaft lever 14 are respectively connected with the cleaning wheels 10 in a coaxial key mode. A plurality of cleaning cloth strips are uniformly wound and fixed on the outer wall of the cleaning wheel 10.

The second shaft lever 14 is also sleeved with a ball bearing, the outer wall of the ball bearing is connected with a support rod 18, and the direction of the support rod 18 is parallel to the horizontal direction. A second rack 16 is fixed to the left end of the strut 18 in a welded manner, and the direction of the second rack 16 is perpendicular to the horizontal direction. When the first shaft 13 is located at the rightmost end of the first guide hole 11, the right side of the gear 17 can be engaged with the second rack 16.

The specific implementation process is as follows: when the window body 1 slides to the left along the first sliding groove 3 or the second sliding groove 4, the first shaft 13 is initially stationary until the inner wall of the first guiding hole 11 on the frame 9 on the right side abuts against the outer wall of the first shaft 13, and then when the window body 1 continues to move to the left, the inner wall of the first guiding hole 11 on the right side abuts against the outer wall of the first shaft 13 and drives the first shaft 13 to move horizontally to the left. Since the gear 17 on the first shaft rod 13 and the first rack 15 on the supporting slide rail 5 are always meshed with each other, and when the first shaft rod 13 is located at the rightmost end of the first guide hole 11, the right side of the gear 17 can be meshed with the second rack 16, the gear 17 can rotate in the circumferential direction under the meshing of the first rack 15, and simultaneously the gear 17 also drives the second rack 16 which is matched with the second guide hole 12 to move vertically upwards. The raising of the second toothed rack 16 simultaneously also drives the cleaning wheel 10 up, which finally effects the cleaning wheel 10 leaving the first runner 3 or the second runner 4 when the window body 1 is moved to the left.

When the window body 1 slides along the first sliding groove 3 or the second sliding groove 4 to the right, the frame 9 moves to the right relative to the first shaft 13, so that the first shaft 13 is stationary relative to the support rail 5, and the frame 9 moves to the right relative to the first shaft 13. In the process of movement, the first shaft 13 is separated relative to the second rack 16, and after the second rack 16 is separated, the second shaft falls under the gravity of the second shaft and the cleaning wheel 10 due to the loss of the limitation of the gear 17, so that the cleaning wheel 10 falls in the first chute 3 or the second chute 4. Finally, in the process that the window body 1 continuously slides rightwards, the cleaning wheel 10 cleans rightwards along the first sliding chute 3 and the second sliding chute 4, so that dust in the first sliding chute 3 and the second sliding chute is concentrated on the right side of the cleaning wheel 10.

Example two

The difference between the first embodiment and the second embodiment is that, as shown in fig. 4, the left bottom surfaces of the first chute 3 and the second chute 4 are respectively provided with a collection hole 6, a cavity 7 is provided right below the first chute 3 and the second chute 4, and both the two collection holes 6 are communicated with the cavity 7. The side wall of the cavity 7 is communicated with the outside, and the dust collection drawer 8 is horizontally connected to the communicated position of the side wall of the cavity 7 in a sliding way.

The specific implementation process comprises the following steps: finally, when the window body 1 moves to the right end of the frame 2, the dust collected on the right side of the cleaning wheel 10 falls into the collecting hole 6, and the dust falls into the dust collection drawer 8 through the collecting hole 6. When accumulated to a certain extent, the operator only has to pull the dust collection drawer 8 out of the cavity 7 and dump the dust.

The foregoing is merely an example of the present invention and common general knowledge of known specific structures and features of the embodiments is not described herein in any greater detail. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the present invention. The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: the window comprises a window body 1, a frame 2, a first sliding chute 3, a second sliding chute 4, a supporting sliding rail 5, a collecting hole 6, a cavity 7, a dust collecting drawer 8, a frame 9, a cleaning wheel 10, a first guide hole 11, a second guide hole 12, a first shaft rod 13, a second shaft rod 14, a first rack 15, a second rack 16, a gear 17 and a support rod 18.

The examples are essentially as follows: as shown in fig. 1, the automatic cleaning and dust removing window comprises two window bodies 1 and a frame 2. The top of the frame 2 is provided with an upper chute group, and the bottom of the frame 2 is provided with a lower chute group. The upper chute group and the lower chute group have the same size and structure.

As shown in fig. 3, the lower chute group includes a first chute 3 and a second chute 4 which are parallel to each other, a supporting slide rail 5 is integrally formed on the bottom surfaces of the first chute 3 and the second chute 4, the supporting slide rail 5 is integrally formed with the first chute 3 and the second chute 4, and the supporting slide rail 5 is parallel to the lower chute group.

The two window bodies 1 are respectively connected to the first sliding chute 3 and the second sliding chute 4 in a sliding manner. The window main body 1 comprises a rectangular frame 9, a glass plate is embedded and fixed on the frame 9, and the frames 9 of the two window main bodies 1 are respectively connected on the first sliding chute 3 and the second sliding chute 4 in a sliding manner.

As shown in fig. 2, a first rack 15 is fixedly connected to the top surface of the supporting slide rail 5, and a first guide hole 11 is formed in the side wall of the lower frame 9, and the first guide hole 11 is parallel to the horizontal direction. A first shaft rod 13 is slidably connected in the first guide hole 11, and the axial direction of the first shaft rod 13 is perpendicular to the first guide hole 11. The first shaft 13 is coaxially and rotatably connected with a gear 17. The gear 17 engages on the first rack 15 supporting the slide 5. The inner walls of the left end and the right end of the first guide hole 11 are both in arc transition, and the radius of the arc transition is equal to the radius of the outer wall of the first shaft rod 13.

The frame 9 is provided with a second guide hole 12 on the right side of the first guide hole 11, the second guide hole 12 is parallel to the vertical direction, and the upper end and the lower end of the second guide hole 12 are both closed. A second shaft 14 is slidably connected in the second guide hole 12, and the axial direction of the second shaft 14 is parallel to the axial direction of the first shaft 13. Both ends of the second shaft lever 14 extend outwards outside the frame 2, and both ends of the second shaft lever 14 are respectively connected with the cleaning wheels 10 in a coaxial key mode. A plurality of cleaning cloth strips are uniformly wound and fixed on the outer wall of the cleaning wheel 10.

The second shaft lever 14 is also sleeved with a ball bearing, the outer wall of the ball bearing is connected with a support rod 18, and the direction of the support rod 18 is parallel to the horizontal direction. A second rack 16 is fixed to the left end of the strut 18 in a welded manner, and the direction of the second rack 16 is perpendicular to the horizontal direction. When the first shaft 13 is located at the rightmost end of the first guide hole 11, the right side of the gear 17 can be engaged with the second rack 16.

The specific implementation process is as follows: when the window body 1 slides to the left along the first sliding groove 3 or the second sliding groove 4, the first shaft 13 is initially stationary until the inner wall of the first guiding hole 11 on the frame 9 on the right side abuts against the outer wall of the first shaft 13, and then when the window body 1 continues to move to the left, the inner wall of the first guiding hole 11 on the right side abuts against the outer wall of the first shaft 13 and drives the first shaft 13 to move horizontally to the left. Since the gear 17 on the first shaft rod 13 and the first rack 15 on the supporting slide rail 5 are always meshed with each other, and when the first shaft rod 13 is located at the rightmost end of the first guide hole 11, the right side of the gear 17 can be meshed with the second rack 16, the gear 17 can rotate in the circumferential direction under the meshing of the first rack 15, and simultaneously the gear 17 also drives the second rack 16 which is matched with the second guide hole 12 to move vertically upwards. The raising of the second toothed rack 16 simultaneously also brings the cleaning wheel 10 up, which finally effects the cleaning wheel 10 leaving the first runner 3 or the second runner 4 when the window body 1 is moved to the left.

When the window body 1 slides to the right along the first sliding groove 3 or the second sliding groove 4, the frame 9 moves to the right relative to the first shaft 13, so that the first shaft 13 is stationary relative to the support rail 5, and the frame 9 moves to the right relative to the first shaft 13. In the process of movement, the first shaft 13 is separated relative to the second rack 16, and after the second rack 16 is separated, the second shaft falls under the gravity of the second shaft and the cleaning wheel 10 due to the loss of the limitation of the gear 17, so that the cleaning wheel 10 falls in the first chute 3 or the second chute 4. Finally, in the process that the window body 1 continuously slides rightwards, the cleaning wheel 10 cleans rightwards along the first sliding chute 3 and the second sliding chute 4, so that dust in the first sliding chute 3 and the second sliding chute is concentrated on the right side of the cleaning wheel 10.

Example two

The difference between the first embodiment and the second embodiment is that, as shown in fig. 4, the bottom surfaces of the left sides of the first chute 3 and the second chute 4 are respectively provided with a collecting hole 6, a cavity 7 is provided right below the first chute 3 and the second chute 4, and both the collecting holes 6 are communicated with the cavity 7. The side wall of the cavity 7 is communicated with the outside, and the dust collection drawer 8 is horizontally connected to the communicated position of the side wall of the cavity 7 in a sliding way.

The specific implementation process comprises the following steps: finally, when the window body 1 moves to the right end of the frame 2, the dust collected on the right side of the cleaning wheel 10 falls into the collecting hole 6, and the dust falls into the dust collection drawer 8 through the collecting hole 6. When accumulated to a certain extent, the operator only has to pull the dust collection drawer 8 out of the cavity 7 and dump the dust.

The foregoing is merely an example of the present invention and common general knowledge of known specific structures and features of the embodiments is not described herein in any greater detail. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the present invention.

Claims (8)

1. The utility model provides an automatic wash ash removal window, includes window main part and spout, window main part sliding connection is on the spout, its characterized in that: the side wall of the window body is provided with a vertical second guide hole, a second shaft lever is connected in the second guide hole in a sliding manner, the second shaft lever is axially vertical to the second guide hole, the end part of the second shaft lever is rotatably connected with a cleaning wheel, and the outer wall of the cleaning wheel abuts against the inner surface of the sliding chute; a supporting sliding rail is fixed on the top surface of the sliding groove, the supporting sliding rail is parallel to the sliding groove, and the window main body slides on the supporting sliding rail; a first rack is fixed at the top of the supporting slide rail, a first guide hole is horizontally formed in the side wall of the window body, a first shaft lever is connected in the first guide hole in a sliding mode and parallel to a second shaft lever, a gear is rotatably connected to the end portion of the first shaft lever and meshed with the first rack, and a vertical second rack is fixedly connected to the side wall of the second shaft lever; the gear can engage the second rack when the first guide hole is located at a side close to the second shaft.

2. The automatic cleaning dust removing window as claimed in claim 1, wherein: the inner walls of the two ends of the first guide hole are arc chamfers.

3. The automatic cleaning dust removing window as claimed in claim 1, wherein: the bottom surface of the sliding chute is provided with a collecting hole, a cavity is arranged below the collecting hole, and the cavity is communicated with the collecting hole.

4. The automatic cleaning dust removing window as claimed in claim 3, wherein: the side wall of the window body is communicated with the cavity, and a dust collection drawer is connected in the cavity in a sliding mode.

5. The automatic cleaning dust removing window as claimed in claim 1, wherein: and a support rod is fixedly connected between the second rack and the second shaft rod.

6. The automatic cleaning dust removing window as claimed in claim 1, wherein: the window main body comprises a frame, and a glass plate is embedded and fixed in the frame.

7. The automatic cleaning dust removing window as claimed in claim 6, wherein: the frame is of a rectangular structure.

8. The automatic cleaning dust removing window as claimed in claim 1, wherein: the outer wall of the cleaning wheel is fixedly connected with a plurality of cleaning cloth strips.

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