CN216811390U - Energy-conserving window of latent fan of high low drainage jump design - Google Patents

Abstract

The utility model discloses a hidden sash energy-saving window with high and low drainage step difference design, which belongs to the technical field of hidden sash energy-saving windows and comprises a window body fixing rod, an equal-pressure cavity and a drainage component, wherein the upper end of the window body fixing rod is provided with a mounting groove, an energy-saving window can be mounted in the mounting groove, the interior of the window body fixing rod is hollow, the drainage component is arranged in the window body fixing rod, the drainage component has high and low potentials, the interior of the window body fixing rod is in a step shape, and the equal-pressure cavity is arranged between the drainage component and the window body fixing rod; the device passes through the equipressure chamber of echelonment, and simple structure does not occupy extra space, improves the sealing performance of latent fan energy-saving window greatly.

Description

Energy-conserving window of latent fan of high low drainage jump design

Technical Field

The utility model belongs to the technical field of energy-saving hidden sash windows, and particularly relates to a hidden sash energy-saving window designed by high and low drainage steps.

Background

With the shortage of energy sources, building energy conservation is gradually paid more and more attention by people. The reasonable selection of the building energy-saving material is a key link for realizing comprehensive building energy saving. The energy-saving window saves energy by reducing indoor heat loss, and the energy-saving window can effectively reduce indoor energy loss by 30 percent. The accumulated water in the isobaric cavity of the outdoor section bar of the traditional energy-saving window system is easy to permeate into the room, and the water tightness and the air tightness are general; the window sashes can be seen from the outside of a traditional energy-saving window system, and the appearance is complex and bloated.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a hidden fan energy-saving window with high and low drainage step difference design, which has a simple structure and occupies no extra space through a stepped constant-pressure cavity, and the sealing performance of the hidden fan energy-saving window is greatly improved.

In order to achieve the purpose, the utility model provides the following technical scheme: energy-conserving window of latent fan of high low drainage jump design, this energy-conserving window of latent fan of high low drainage jump design include window form dead lever, isobaric chamber, drainage component, the mounting groove has been seted up to window form dead lever upper end, the energy-conserving window of the inside mountable of mounting groove, the inside hollow form that is of window form dead lever, the inside drainage component that is of window form dead lever, drainage component have the height potential, are the echelonment inside the window form dead lever, are equipped with the isobaric chamber between drainage component and the window form dead lever.

Furthermore, ventilation holes are formed in two sides of the window body fixing rod and penetrate through the window body fixing rod, and a plurality of ventilation holes are formed in the length direction of the window body fixing rod.

Adopt above-mentioned scheme: the ventilation effect of the energy-saving window can be realized.

Further, the inside partition panel that is fixed with of window form dead lever, partition panel are located ventilation hole top, form the air convection chamber between partition panel and the window form dead lever bottom.

Adopt above-mentioned scheme: preventing water from entering the air convection chamber.

Further, the drainage subassembly is including fixing the inside hang plate of window form dead lever, the hang plate below is equipped with the ladder board of fixing inside the window form dead lever, is equipped with the discharge orifice on the hang plate, does between ladder board and the hang plate constant pressure chamber, cavity between hang plate top and the window form dead lever are the chamber of catchmenting, through the discharge orifice intercommunication between chamber of catchmenting and the constant pressure chamber, the ladder board with form the flow chamber between the partition panel, the constant pressure chamber upper end is equipped with the convection hole of seting up on the window form dead lever.

Adopt above-mentioned scheme: through the stepped constant-pressure cavity, the structure is simple, extra space is not occupied, and the sealing performance of the hidden-fan energy-saving window is greatly improved.

Further, the water collecting hole has been seted up to the chamber upper end that catchments, and first apopore has been seted up to the chamber lower extreme that catchments, and the water collecting hole all is equipped with a plurality ofly along window body dead lever length direction with first apopore.

Adopt above-mentioned scheme: facilitating the drainage of water.

Further, reposition of redundant personnel chamber upper end is equipped with sets up intercommunicating pore on the notch cuttype board, the lower extreme is equipped with the second apopore of seting up on the window body dead lever, and intercommunicating pore and second apopore all are equipped with a plurality ofly along window body dead lever length direction.

Adopt above-mentioned scheme: set up the intercommunicating pore on the notch cuttype board, rivers can flow back once more under the effect of self gravitational potential energy, utilize the echelonment, reduce rivers rising speed, promote water discharge efficiency, and then improve sealed effect.

Further, the inside connecting rod that is fixed with of convection current hole, the connecting rod sets up a plurality ofly along convection current hole circumferencial direction, and all connecting rods are kept away from the convection current hole end and are fixed with the montant, and the montant upper end is fixed with the apron, and the lower extreme is fixed has the toper piece.

Adopt above-mentioned scheme: through the inclined plane that the toper piece set up, can improve the water and rise the degree of difficulty, reduce water and ooze, the while is favorable to forming the constant pressure chamber to the discharge orifice setting, is convenient for rivers play.

The utility model has the beneficial effects that:

1. through the stepped constant-pressure cavity, the structure is simple, extra space is not occupied, and the sealing performance of the hidden-fan energy-saving window is greatly improved.

2. Set up the intercommunicating pore on the notch cuttype board, rivers can flow back once more under the effect of self gravitational potential energy, utilize the echelonment, reduce rivers rising speed, promote water discharge efficiency, and then improve sealed effect.

3. Through the inclined plane that the toper piece set up, can improve the water and rise the degree of difficulty, reduce water and ooze, the while is favorable to forming the constant pressure chamber to the discharge orifice setting, is convenient for rivers play.

Drawings

FIG. 1 is a schematic structural view of a hidden energy-saving window with high and low drainage step difference design according to the present invention;

FIG. 2 is a schematic side view of the energy saving window with hidden sash according to the present invention;

FIG. 3 is a schematic view of an internal structure of a window fixing rod of the energy saving window with hidden sash having a high-low drainage step difference design according to the present invention;

FIG. 4 is an enlarged view of the hidden energy saving window with high and low drainage steps shown in FIG. 3;

fig. 5 is an enlarged schematic view of the hidden fan energy-saving window with high and low drainage step difference design shown at II in fig. 3.

In the figure: 1. a window body fixing rod; 2. an equal-pressure cavity; 3. a drainage assembly; 4. mounting grooves; 5. a vent hole; 6. a partition panel; 7. an air convection cavity; 8. an inclined plate; 9. a step plate; 10. a water flowing hole; 11. a water collection cavity; 12. a shunting cavity; 13. a convection hole; 14. a water collection hole; 15. a first water outlet; 16. a communicating hole; 17. a second water outlet; 18. a connecting rod; 19. a vertical rod; 20. a cover plate; 21. and (5) a conical block.

Detailed Description

In order to further understand the contents, features and effects of the present invention, the following embodiments are illustrated and described in detail with reference to the accompanying drawings.

Referring to fig. 1 to 5, the hidden fan energy saving window with high and low drainage steps according to the embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in fig. 1, the hidden sash energy-saving window with high and low drainage step difference design comprises a window body fixing rod 1, an equal pressure cavity 2 and a drainage component 3, wherein a mounting groove 4 is formed in the upper end of the window body fixing rod 1, the energy-saving window can be mounted in the mounting groove 4, the window body fixing rod 1 is hollow, the drainage component 3 is arranged in the window body fixing rod 1, the drainage component 3 has high and low potentials and is in a step shape in the window body fixing rod 1, and the equal pressure cavity 2 is arranged between the drainage component 3 and the window body fixing rod 1.

Specifically, ventilation hole 5 has been seted up to 1 both sides of window form dead lever, and ventilation hole 5 runs through inside 1 window form dead lever, is equipped with a plurality ofly along 1 length direction of window form dead lever.

Wherein, window form fixed lever 1 inside is fixed with partition panel 6, and partition panel 6 is located ventilation hole 5 top, forms air convection chamber 7 between partition panel 6 and the 1 bottom of window form fixed lever.

Make the circulation of air through ventilation hole 5 on window form dead lever 1 in the window with the window is outer, forms air convection chamber 7, sets up partition panel 6 in air convection chamber 7 upper end simultaneously, and partition panel 6 is fixed the setting, can block water entering air convection chamber 7.

Specifically, drainage component 3 is including fixing the inside hang plate 8 of window form dead lever 1, 8 below of hang plate are equipped with fixes the ladder board 9 in window form dead lever 1 inside, are equipped with discharge orifice 10 on the hang plate 8, do between ladder board 9 and the hang plate 8 constant pressure chamber 2, the cavity between 8 tops of hang plate and the window form dead lever 1 is for catchmenting chamber 11, catchments through discharge orifice 10 intercommunication between chamber 11 and the constant pressure chamber 2, ladder board 9 with form component flow chamber 12 between the partition panel 6, constant pressure chamber 2 upper end is equipped with the convection hole 13 of seting up on window form dead lever 1.

Wherein, the hole 14 that catchments has been seted up to 11 upper ends in chamber that catchments, and first apopore 15 has been seted up to 11 lower extremes in chamber that catchments, and the hole 14 that catchments all is equipped with a plurality ofly along 1 length direction of window form dead lever with first apopore 15.

When raining outside the window, rainwater enters the inside of the window body fixing rod 1 along the water collecting hole 14, and after entering, the rainwater is drained through the first water outlet 15 along the inclined plate 8.

Be equipped with in reposition of redundant personnel chamber 12 upper end and establish intercommunicating pore 16 on the notch cuttype board 9, the lower extreme is equipped with the second apopore 17 of seting up on window form dead lever 1, and intercommunicating pore 16 all is equipped with a plurality ofly along 1 length direction of window form dead lever with second apopore 17.

The residual water after the water is discharged through the first water outlet 15 enters the constant pressure cavity 2 through the water discharge hole 10, flows into the lower step of the step plate 9, enters the upper step along with the rising of the water, and the water entering the upper step can return to the lower part of the step plate 9 along the communication hole 16 and flows out through the second water outlet 17.

And the inside of the convection hole 13 is fixed with a connecting rod 18, the connecting rods 18 are arranged along the circumferential direction of the convection hole 13, a vertical rod 19 is fixed on the end of each connecting rod 18 far away from the convection hole 13, a cover plate 20 is fixed on the upper end of each vertical rod 19, and a conical block 21 is fixed on the lower end of each vertical rod.

When seepage water flows to the convection hole 13 through the water sealed by the constant pressure cavity 2, the conical block 21 arranged on the convection hole 13 further prevents the seepage of the water through the self inclined surface.

The working principle of the utility model is as follows: through setting up convection hole 13 and discharge orifice 10, second apopore 17 formation isobaric chamber 2, set up ladder board 9 in isobaric chamber 2 inside, inside rivers are under the ladder effect, under self gravitational potential energy, preferentially flow back to ladder board 9 below through intercommunicating pore 16, prevent effectively that rivers from overflowing to convection hole 13 department, and then seal.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. Energy-conserving window of latent fan of high low drainage jump design, its characterized in that, this energy-conserving window of latent fan of high low drainage jump design includes window form dead lever (1), isobaric chamber (2), drainage component (3), mounting groove (4) have been seted up to window form dead lever (1) upper end, the energy-conserving window of the inside mountable of mounting groove (4), the inside hollow form that is of window form dead lever (1), inside drainage component (3) that are equipped with of window form dead lever (1), drainage component (3) have the height potential, are the echelonment in window form dead lever (1) inside, are equipped with isobaric chamber (2) between drainage component (3) and window form dead lever (1).

2. The energy-saving window with hidden sash with high and low drainage step difference as claimed in claim 1, wherein the window fixing rod (1) is provided with a plurality of ventilation holes (5) at both sides thereof, the ventilation holes (5) penetrate through the inside of the window fixing rod (1), and the plurality of ventilation holes are arranged along the length direction of the window fixing rod (1).

3. The energy-saving window with hidden fan and high and low drainage step designed according to claim 1 is characterized in that a partition plate (6) is fixed inside the window fixing rod (1), the partition plate (6) is located above the ventilation holes (5), and an air convection cavity (7) is formed between the partition plate (6) and the bottom of the window fixing rod (1).

4. The energy-saving window with hidden sash and high and low drainage step difference designed according to claim 3, wherein the drainage component (3) comprises an inclined plate (8) fixed inside the window fixing rod (1), a step plate (9) fixed inside the window fixing rod (1) is arranged below the inclined plate (8), a water flowing hole (10) is formed in the inclined plate (8), the constant pressure cavity (2) is formed between the step plate (9) and the inclined plate (8), a water collecting cavity (11) is formed between the upper part of the inclined plate (8) and the window fixing rod (1), the water collecting cavity (11) is communicated with the constant pressure cavity (2) through the water flowing hole (10), a component flow cavity (12) is formed between the step plate (9) and the partition plate (6), and an convection hole (13) formed in the window fixing rod (1) is formed in the upper end of the constant pressure cavity (2).

5. The energy-saving window with hidden sash and high and low drainage step designed according to claim 4, wherein the upper end of the water collecting cavity (11) is provided with a water collecting hole (14), the lower end of the water collecting cavity (11) is provided with a first water outlet hole (15), and the water collecting hole (14) and the first water outlet hole (15) are both provided with a plurality of water collecting holes along the length direction of the window fixing rod (1).

6. The energy-saving window with hidden sash and high and low drainage step designed according to claim 4, wherein the upper end of the diversion chamber (12) is provided with a communication hole (16) formed on the step plate (9), the lower end of the diversion chamber is provided with a second water outlet hole (17) formed on the window fixing rod (1), and the communication hole (16) and the second water outlet hole (17) are both provided with a plurality of water outlet holes along the length direction of the window fixing rod (1).

7. The hidden fan energy-saving window designed according to the high and low drainage step difference of claim 4, wherein the convection hole (13) is internally fixed with a plurality of connecting rods (18), the connecting rods (18) are arranged along the circumferential direction of the convection hole (13), the end of each connecting rod (18) far away from the convection hole (13) is fixed with a vertical rod (19), the upper end of each vertical rod (19) is fixed with a cover plate (20), and the lower end of each vertical rod is fixed with a conical block (21).

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