CN218844132U - Improved hollow LOW-E glass - Google Patents

Abstract

The utility model discloses an improved generation cavity LOW-E glass relates to glass technical field, uses the frame to propagate sound and can't judge the problem whether the inside argon gas of cavity glass diminishes as the medium to current sound easily, and the following scheme is proposed at present, and it includes the frame, the bottom of frame is provided with the underframe, the lateral wall of underframe and frame is provided with spacing frame, spacing frame is the symmetry setting with the axis of underframe, be provided with sound insulation structure between spacing frame and the frame, sound insulation structure is used for the propagation of noise reduction, the inside of frame is provided with and is used for observing the extending structure whether argon gas diminishes, sound insulation structure includes sound insulation pad, spacing hole, fixture block and draw-in groove. The utility model discloses improved generation cavity LOW-E glass can effectual reduction external noise use the frame to propagate indoor as the medium for the sound insulation effect has obtained the improvement, just can judge through the position of observing the movable plate simultaneously whether glass inside argon gas lacks.

Description

Improved hollow LOW-E glass

Technical Field

The utility model relates to a glass technical field especially relates to an improved generation cavity LOW-E glass.

Background

Argon is generally filled in the LOW-E glass, so that the sound insulation effect of the glass can be effectively improved, but the periphery of the glass is provided with an installation frame, sound of the installation frame is easy to propagate by taking the fixed installation frame as a medium, the argon in the hollow glass is reduced in the using process and needs to be supplemented, when the argon is reduced, the sound insulation effect is poor, and whether the argon in the hollow glass is reduced cannot be judged, so that the improved hollow LOW-E glass is provided for solving the problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides an improved generation cavity LOW-E glass has solved sound and has used the frame to propagate sound and can't judge the problem whether the inside argon gas of cavity glass becomes less as the medium easily.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides an improved generation cavity LOW-E glass, includes the frame, the bottom of frame is provided with the underframe, the lateral wall of underframe and frame is provided with spacing frame, spacing frame is the symmetry setting with the axis of underframe, be provided with sound insulation structure between spacing frame and the frame, sound insulation structure is used for the propagation of noise reduction, the inside of frame is provided with and is used for observing the extending structure whether argon gas diminishes, sound insulation structure includes sound insulation pad, spacing hole, fixture block and draw-in groove, spacing hole site is in one side that sound insulation filled up, just spacing hole passes sound insulation pad and extends to the outside, spacing hole is the symmetry setting with sound insulation pad's axis.

Preferably, the fixture block is located on one side of the limiting frame close to the sound insulation pad, and the clamping groove is located on one side of the frame and the bottom frame close to the sound insulation pad.

Preferably, the clamping block penetrates through the sound insulation pad and extends to the inside of the clamping groove, and the clamping groove is matched with the clamping block.

Preferably, the buckle is installed to the bottom of frame, the buckle is the symmetry setting with the axis of frame, the top of underframe is provided with the mounting groove.

Preferably, mounting groove and extending structure phase-match, the top of underframe is provided with the fixed slot, the fixed slot is the symmetry setting with the axis of underframe, fixed slot and buckle phase-match.

Preferably, the telescopic structure comprises first glass, second glass, third glass, a fixed block, a limiting block, a moving plate, a sliding rod, a rubber plug and a telescopic spring, wherein the first glass and the second glass are positioned on two sides of the third glass.

Preferably, one end of the fixing block is connected with the third glass, the fixing block is symmetrically arranged on the central axis of the third glass, and the rubber plug is located inside the fixing block.

Preferably, the circumference lateral wall at the rubber buffer is established to the expanding spring cover, expanding spring's one end is connected with the rubber buffer, just expanding spring keeps away from the one end of rubber buffer and is connected with the fixed block.

Preferably, the end of the rubber plug far away from the telescopic spring is connected with the sliding rod, and the end of the sliding rod far away from the rubber plug penetrates through the fixed block and the limiting block to be connected with the moving plate.

Preferably, the limiting block is connected with the sliding rod in a sliding mode, the moving plate is located inside the limiting block, and the limiting block is matched with the first glass and the second glass.

The utility model has the advantages that:

1. through being provided with between frame and spacing frame and give sound insulation and fill up to can effectual reduction external noise use the frame to propagate to indoorly as the medium, make the effect that gives sound insulation obtain the improvement.

2. Through filling argon gas in glass's inside, can make the pressure ratio of glass inside big than fixed block internal pressure when filling argon gas to make the rubber buffer drive expanding spring compress, when argon gas lacks, its internal pressure diminishes and can remove through the effectual movable plate that drives of expanding spring's elasticity effect, just can judge through the position of observing the movable plate whether argon gas of glass inside lacks.

To sum up, the device can effectually reduce the external noise and use the frame to propagate to indoorly as the medium for the syllable-dividing effect has obtained improving, just can judge whether glass inside argon gas lacks through the position of observing the movable plate simultaneously.

Drawings

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

Fig. 2 is a schematic view of the split structure of the present invention.

Fig. 3 is a bottom view of the detachable structure of the present invention.

Fig. 4 is an enlarged schematic view of a portion a in fig. 3 according to the present invention.

Fig. 5 is a schematic view of the telescopic structure of the present invention.

The reference numbers in the figures: 1. a frame; 2. a bottom frame; 3. a limiting frame; 4. a sound-insulating structure; 401. a sound insulating pad; 402. a limiting hole; 403. a clamping block; 404. a card slot; 5. a telescopic structure; 501. a first glass; 502. a second glass; 503. a third glass; 504. a fixed block; 505. a limiting block; 506. moving the plate; 507. a slide bar; 508. a rubber plug; 509. a tension spring; 6. mounting grooves; 7. fixing grooves; 8. and (6) buckling.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1 to 5, an improved hollow LOW-E glass includes a frame 1, a bottom frame 2 is disposed at a bottom end of the frame 1, a limiting frame 3 is disposed on side walls of the bottom frame 2 and the frame 1, the limiting frame 3 is symmetrically disposed about a central axis of the bottom frame 2, a sound insulation structure 4 is disposed between the limiting frame 3 and the frame 1, the sound insulation structure 4 is used for reducing noise propagation, a telescopic structure 5 for observing whether argon gas is reduced is disposed inside the frame 1, the sound insulation structure 4 includes a sound insulation pad 401, a limiting hole 402, a clamping block 403 and a clamping groove 404, the limiting hole 402 is disposed on one side of the sound insulation pad 401, the limiting hole 402 penetrates through the sound insulation pad 401 and extends to the outside, the limiting hole 402 is symmetrically disposed about the central axis of the sound insulation pad 401, the clamping block 403 is disposed on one side of the limiting frame 3 close to the sound insulation pad 401, the clamping groove 404 is disposed on one side of the frame 1 and the bottom frame 2 close to the sound insulation pad 401, the clamping block 403 penetrates through the internal clamping block 401 and extends to the clamping groove 404, and the clamping block is matched with the clamping groove 403.

As shown in fig. 2 and 3, buckle 8 is installed to the bottom of frame 1, buckle 8 is the symmetry setting with the axis of frame 1, the top of underframe 2 is provided with mounting groove 6, mounting groove 6 and extending structure 5 phase-match, the top of underframe 2 is provided with fixed slot 7, fixed slot 7 is the symmetry setting with the axis of underframe 2, fixed slot 7 and buckle 8 phase-match can be connected frame 1 and underframe 2 through buckle 8 and fixed slot 7, then is connected through draw-in groove 404 and fixture block 403 between frame 1 and the spacing frame 3.

As shown in fig. 2-5, the telescopic structure 5 includes a first glass 501, a second glass 502, a third glass 503, a fixed block 504, a stop block 505, a moving plate 506, a sliding rod 507, a rubber plug 508 and a telescopic spring 509, the first glass 501 and the second glass 502 are located at two sides of the third glass 503, one end of the fixed block 504 is connected with the third glass 503, the fixed block 504 is symmetrically disposed about the central axis of the third glass 503, the rubber plug 508 is located inside the fixed block 504, the telescopic spring 509 is sleeved on the circumferential side wall of the rubber plug 508, one end of the telescopic spring 508 is connected with the rubber plug 508, one end of the telescopic spring 509 far away from the rubber plug 508 is connected with the fixed block 504, one end of the rubber plug 508 far away from the telescopic spring is connected with the sliding rod 507 through the fixed block 504 and the stop block 505, the stop block 505 is connected with the sliding rod 507, the moving plate 506 is located inside the stop block 505, the stop block 505 is connected with the first glass 501 and the second glass 502, the end of the sliding rod 507 passes through the fixed block 504 and the stop block 505 and the telescopic spring 509, and the moving plate 506 is capable of moving according to the outside, so as to determine whether the moving plate 506 is capable of viewing from the outside.

The working principle is as follows: when the device is used, parts needing to be installed are moved to an assembly table for assembly, then, a first glass 501 and a second glass 502 are moved to the inside of a limiting block 505 from the side face, the moving plate 506 is pressed while the device is installed, the moving plate 506 compresses a telescopic spring 509, the first glass 501 and the second glass 502 can be effectively limited, then, the first glass 501, the second glass 502 and a third glass 503 are clamped in an installation groove 6 of a bottom frame 2, then, a clamping buckle 8 at the bottom end of a frame 1 is inserted into the inside of a fixing groove 7, the frame 1 can be effectively fixed on the bottom frame 2, then, a clamping block 403 on a limiting frame 3 penetrates through a sound insulation pad 401 to be connected with a clamping groove 404, external noise can be effectively reduced through the sound insulation pad 401, the frame 1 and the bottom frame 2 serve as media to be propagated into a room, the sound insulation effect can be effectively improved, after the installation, sealant is applied to the edge of the glass after the installation, then, argon gas is filled into the glass, when the argon gas is filled, the pressure inside of the fixing block 504 is higher than the pressure inside of the glass, thereby, the pressure of the glass can be effectively reduced, whether the inner pressure of the moving plate 508 can be effectively judged, whether the inner pressure of the telescopic spring 508, the moving plate 506 is reduced, whether the inner pressure of the telescopic spring, and the telescopic spring 508 can be reduced, and whether the inner pressure of the moving plate can be reduced, and the telescopic spring 509, and whether the moving plate can be judged when the inner pressure of the telescopic spring, and the telescopic spring 508 can be reduced, and the telescopic spring 508 can be reduced.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (10)

1. The utility model provides an improved generation cavity LOW-E glass, includes frame (1), its characterized in that, the bottom of frame (1) is provided with underframe (2), the lateral wall of underframe (2) and frame (1) is provided with spacing frame (3), spacing frame (3) are the symmetry setting with the axis of underframe (2), be provided with sound-proof structure (4) between spacing frame (3) and frame (1), sound-proof structure (4) are used for the propagation of noise reduction, the inside of frame (1) is provided with and is used for observing whether the extending structure (5) that argon gas diminishes, sound-proof structure (4) are including sound-proof pad (401), spacing hole (402), fixture block (403) and draw-in groove (404), spacing hole (402) are located the one side of sound-proof pad (401), just spacing hole (402) pass sound-proof pad (401) and extend to the outside, spacing hole (402) are the symmetry setting with the axis of sound-proof pad (401).

2. An improved hollow LOW-E glass as claimed in claim 1, wherein said fixture block (403) is located at one side of the position-limiting frame (3) close to the sound insulation pad (401), and said fixture groove (404) is located at one side of the frame (1) and the bottom frame (2) close to the sound insulation pad (401).

3. An improved hollow LOW-E glass as claimed in claim 1, wherein said fixture block (403) extends through the sound isolation pad (401) to the inside of the fixture groove (404), and said fixture groove (404) matches with the fixture block (403).

4. An improved hollow LOW-E glass as claimed in claim 1, wherein the bottom end of the frame (1) is installed with a buckle (8), the buckle (8) is symmetrically arranged with the central axis of the frame (1), and the top end of the bottom frame (2) is provided with an installation groove (6).

5. The improved hollow LOW-E glass as claimed in claim 4, wherein said mounting groove (6) is matched with a telescopic structure (5), a fixing groove (7) is arranged on the top end of said bottom frame (2), said fixing groove (7) is symmetrically arranged with the central axis of said bottom frame (2), said fixing groove (7) is matched with a buckle (8).

6. The improved hollow LOW-E glass according to claim 1, wherein the telescopic structure (5) comprises a first glass (501), a second glass (502), a third glass (503), a fixed block (504), a limited block (505), a moving plate (506), a sliding rod (507), a rubber plug (508) and a telescopic spring (509), and the first glass (501) and the second glass (502) are positioned at two sides of the third glass (503).

7. The improved hollow LOW-E glass as claimed in claim 6, wherein one end of the fixing block (504) is connected with a third glass (503), the fixing block (504) is symmetrically arranged with the central axis of the third glass (503), and the rubber plug (508) is positioned inside the fixing block (504).

8. The improved hollow LOW-E glass as claimed in claim 6, wherein said extension spring (509) is sleeved on the circumferential side wall of the rubber plug (508), one end of said extension spring (509) is connected with the rubber plug (508), and the end of said extension spring (509) far away from the rubber plug (508) is connected with the fixing block (504).

9. The improved hollow LOW-E glass as claimed in claim 6, wherein the end of the rubber plug (508) far away from the extension spring (509) is connected with a sliding rod (507), and the end of the sliding rod (507) far away from the rubber plug (508) is connected with the moving plate (506) through the fixed block (504) and the limited block (505).

10. An improved hollow LOW-E glass as claimed in claim 6, wherein said stopper (505) is connected with a sliding rod (507) in a sliding manner, and said moving plate (506) is located inside the stopper (505), and said stopper (505) is matched with the first glass (501) and the second glass (502).

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