JPS6240062Y2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention relates to a sash frame equipped with a ventilation device that forcibly blows indoor air (inside air) to the outside or indoors.

Conventionally, this type of ventilation equipment was manufactured by Jikosho, for example.
As shown in Publication No. 46-33646, an outdoor suction port, an outdoor discharge port, an indoor suction port, and an indoor discharge port are formed in the wind cylinder that is attached to the ventilation port of the structure, and a partition plate is installed inside the wind cylinder. a first passage connecting the outdoor side suction port and the indoor side discharge port and a second passage connecting the outdoor side discharge port and the indoor side suction port; It is known that a heat exchanger is provided at the intersection of the first and second passages.

With this structure, the difference between the temperature of the outside air and the inside air that is blown into the room can be reduced by exchanging heat between outside air and inside air, and the inside of the building (indoors) can be ventilated without significantly reducing heating and cooling efficiency. .

However, with this structure, the indoor side discharge port and the indoor side suction port are formed directly on the wind cylinder, so the indoor side discharge port and the indoor suction port are located adjacent to each other, and only a portion of the interior of the building in the lateral direction is Outside air is discharged to the outside air, and inside air is sucked in only from a portion adjacent to the outside air discharge position.

For this reason, if the above-mentioned ventilation device is attached directly to the sash frame to create a sash frame with a ventilation device, the inside air will flow smoothly in a part of the lateral direction inside the building, but the inside air will flow smoothly in the part away from the indoor exhaust and suction ports. The inside of the building cannot be ventilated efficiently because the air does not flow smoothly.

This invention was developed in view of the above circumstances, and its purpose is to reduce the temperature difference between outside air and inside air, and to draw outside air into the building for ventilation.
To provide a sash frame with a ventilation device, which allows internal air to flow smoothly throughout the inside of a building, allows efficient ventilation, and facilitates construction and installation of the ventilation device.

Embodiments of the present invention will be described below with reference to the drawings.

Figure 1 is a front view of the sash frame, and the sash frame A
The upper frame 1, the lower frame 2, the left and right vertical frames 3, 3, and the blinds 4 connected between the left and right vertical frames 3, 3 form a shoji mounting opening a and an upper opening b, and the shoji mounting opening a The inner and outer shoji 5 ₁ , 5 ₂ are installed in a sliding manner, and a pair of vertical bars 6 , 6 are attached across the upper frame 1 and the no-mume 4 to connect the upper opening b to both side transoms b ₁ , b ₂ and an intermediate ventilation opening b ₃ , and the transoms on both sides b ₁ and b ₂ are fitted with panel members such as glass or fittings 7 such as external folding windows, and the intermediate ventilation opening b ₃
A wind cylinder 8 of a ventilation system is attached to the .

As shown in FIGS. 2 and 3, the wind cylinder 8 has upper and lower walls 8a, 8b, outdoor and inner walls 8c, 8d, and both side walls 8.
e, 8e form a box shape, and upper and lower walls 8a, 8b
and both side walls 8e, 8e are divided into indoor and outdoor directions and are connected with screws 10 via a heat insulating material 9, and an outdoor side suction port 11 and an outdoor side discharge port 12 are formed in the outdoor wall 8c, An indoor side discharge port 13 is formed in the indoor wall 8d, an indoor side suction port 14 is formed in the indoor side portion of the lower wall 8b, and the wind cylinder 8
A partition plate 15 is provided inside the outdoor suction port 11.
A first passage 16 that communicates with the indoor side discharge port 13 and a second passage 17 that communicates the outdoor side discharge port 12 and the indoor side suction port 14 are segmented, and the first and second passages 16 and 17 have a First and second blowers 19 and 20 driven by a motor 18 are provided, respectively, and a heat exchanger 21 is provided at the intersection of the first and second passages 16 and 17 to exchange heat between outside air and inside air. I have made it possible.

In other words, the first and second passages 16 and 17 have an indoor side 16a and 17a and an outdoor side 1 with the heat exchanger 21 as a boundary.
6b, 17b, and the upper and lower walls 8a, 8b and both side walls 8e, 8e are divided into indoor sides 8'a, 8'b, which form indoor passages 16a, 17a.
8'e and outdoor side 8''a, 8''b, 8''e which form outdoor passages 16b, 17b, and are connected with screws 10 through heat insulating material 9 as mentioned above to allow outside air to flow through. It is designed not to directly touch the indoor sides 8'a, 8'b, and 8'e.

The upper frame 1 has an indoor side member 30 and an outdoor side member 31.
and both members 30 and 31 have a heat insulating material 32.
At the same time, the bent piece 33 of the indoor upper wall 8'a of the wind cylinder 8 comes into contact with the hanging wall 30a of the indoor side member 30 via the packing 34, and the hanging wall 30a of the indoor side member 30 The gasket 37 of the presser frame 36, which is fastened to the wall 31a with screws 35, is in contact with the bent piece 38 of the upper wall 8''a on the outside of the wind barrel, and the bent piece 33,
38 are connected with a screw 10 via a heat insulating material 9, and the bent pieces 33 and 38 are clamped and supported via the heat insulating material 9.

The mesh 4 has an indoor side member 40 and an outdoor side member 41
are connected via a heat insulating material 42, and the indoor member 40 forms a hollow frame material with upper and lower walls 40a, 40b and indoor and outer walls 40c, 40d, and both ends are closed to form a hollow part 40'. In addition, an opening 43 that communicates with the indoor suction port 14 is formed in the upper wall 40a, a suction port 44 is formed in both longitudinal ends of the lower wall 40b, and an opening 44 is formed in the upper part of the outdoor wall 40d. The wind body 8 is attached to the provided packing 45.
The bent piece 46 formed on the lower indoor wall 8'b of the wind cylinder 8 comes into contact with the gasket 49 of the holding frame 48 tightened to the outdoor member 41 with screws 47.
The bent pieces 46 and 50 are connected with a screw 10 via a heat insulating material 9. Thereby, the lower wall 8b is clamped and supported by the mesh 4.

The vertical bar 6 has an indoor side member 60 and an outdoor side member 61.
The bent piece 64 of the indoor side wall 8'e abuts against the gasket 63 provided on the indoor side member 60, and the outdoor side member 6
A gasket 67 of a presser frame member 66 fixed to the frame member 1 with screws 65 comes into contact with a bent piece 68 of the outdoor side wall 8″e, and the bent pieces 68 and 64 are connected with a screw 10 via a heat insulating material 9. As a result, the side wall 8e
is clamped and supported by the vertical crosspiece 6.

Therefore, the indoor air inside the building is
The air is sucked in through the air intake port 44 of the indoor member 40 of the blind 4 which is further away, flows into the indoor suction port 14 through the hollow part 40 and the opening 43 of the indoor member 40 of the blind 4, and is then injected into the indoor suction port 14 in the heat exchanger 21. After being ventilated with outside air, it is discharged to the outside from the outdoor outlet 12.

Therefore, as shown in FIGS. 4a, b, and c, the inside air inside the building flows smoothly and ideally over the entire area, allowing efficient ventilation.

In addition, a wind cylinder 8 is installed in a rectangular intermediate ventilation opening b ₃ consisting of the upper frame 1 and the blind 4 of the sash frame A, and a pair of vertical bars 6, 6.
, the ventilation system can be easily attached to the sash frame A.

In addition, the upper frame 1, the blind 4, and the vertical frame 6 are the indoor side members 3.
0, 40, 60 and the outdoor side members 31, 41, 61 are connected via heat insulating materials 32, 42, 62, and the hollow part 4 of the indoor side member 40 with no opening 4
Since the inside air flows through the hollow part 40', the inside air flowing through the hollow part 40' does not come into direct contact with the outside air, and when the inside air flows through the hollow part 40', it maintains its temperature without exchanging heat with the outside air. It flows into the heat exchanger 21.

Therefore, the heat exchanger 21 exchanges heat between the inside air and the outside air, and the temperature of the outside air flowing into the inside can be made to be a temperature that is not much different from the temperature of the inside air, and the efficiency of heating and cooling can be reduced. Ventilation can be carried out without deterioration.

In particular, when the temperature difference between the outside air and the inside air is large, the inside air flows into the heat exchanger 21 while maintaining the large temperature difference, so that the heat exchange efficiency between the inside air and the outside air in the heat exchanger 21 can be improved.

On the other hand, in the case of the open air 4 without any insulation material, when the inside air flowing through this hollow part comes into contact with the outside air, the inside air flows into the heat exchanger 21 with the temperature difference between it and the outside air reduced. The heat exchange efficiency between the inside air and the outside air in the heat exchanger 21 decreases, and outside air having a large temperature difference with the inside air flows into the inside, resulting in a decrease in heating/cooling efficiency.

It should be noted that it is sufficient to achieve the above effects by simply dividing only the blind 4 into indoor and outer members 40 and 41 and connecting them with the heat insulating material 42.

Further, the wind barrel 8 is divided into an indoor side and an outdoor side, which are connected by a heat insulating material 9, and have first and second passages 16, 1
7 on the indoor side 16a, 17a and the outdoor side 16b, 17
Since the indoor sides 16a and 17a are divided into 2 parts and 17b to prevent direct contact with the outside air, the heat exchange efficiency in the heat exchanger 21 is further improved.

In addition, both ends of the blind 4 are opened and communicated with the insides of the vertical frames 3, 3 on both sides, and the vertical frames 3, 3 on both sides are opened and communicated with the lower frame 2, and an intake port 44 is formed in the lower frame 2. Also good.

Since the sash frame with ventilation device of the present invention is as described above, if the sash frame is attached to the building frame, the inside air inside the building can be removed from the wind cylinder from a position far away from the indoor side discharge port 13 of the wind cylinder 8. 8 can be inhaled,
Internal air flows smoothly throughout the entire interior of the building, allowing for efficient ventilation.

Furthermore, since the wind cylinder 8 only needs to be attached to the ventilation port _b3 of the sash frame A, the ventilation device can be easily attached to the sash frame A.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention.
The figure is a front view of the sash frame, Figure 2 is a sectional view taken along the - line, Figure 3 is a sectional view taken along the - line in Figure 1, and Figures 4 a, b, and c are plan views showing the inside air flow inside the building.
They are a front view and a side view. A is the sash frame, b ₃ is the ventilation port, 8 is the wind barrel, 11 is the outdoor suction port, 12 is the outdoor discharge port, 13 is the indoor discharge port, 14 is the indoor suction port, 16 and 17 are the first , a second passage, 19 and 20 are first and second blowers,
21 is a heat exchanger, and 44 is an intake port.

Claims (1)

[Scope of utility model registration request] A ventilation port b ₃ is formed in the sash frame A, and a wind cylinder 8 is installed inside the ventilation port b ₃ , and an outdoor side suction port 11, an outdoor side discharge port 12, and an indoor side discharge port 1 are attached to the wind cylinder 8.
3. A first passage 16 that communicates the indoor suction port 14, the outdoor suction port 11, and the indoor discharge port 13, and a second passage 17 that communicates the outdoor discharge port 12 and the indoor suction port 14 are formed. , and first and second passages 16,
17 facing the first and second blowers 19, 20, the first,
A heat exchanger 21 is provided at the intersection of the second passages 16 and 17, and the indoor suction port 14 is connected to the sash frame A.
The opening communicates with the hollow part of the horizontal frame that constitutes the
An intake port 44 in which the hollow portion is formed at a position laterally far away from the indoor side exhaust port 13 in the horizontal frame.
A satsushi frame with a ventilation system characterized by communicating with the.