KR20060136302A - Diffuser for air conditioning that air conditioning air supply direction is changed automatically - Google Patents

Abstract

The present invention relates to an air conditioning diffuser installed in the ceiling of a building and improved to automatically change the supply direction of air supplied to the room by the temperature of the cooling air or heating air supplied from the air conditioner. Wax filled with air temperature through the air passing through the air through the air (11) having a frame 10 is fixed to the ceiling member (2) is supplied with cooling, heating air from As 21 causes the air guide vane 30 to be rotated by the operation of the temperature sensing cylinder 20 with the piston rod 22 being expanded and contracted; The pressure member 23 coupled to the piston rod 22 of the temperature sensing cylinder 20 installed to be fixed to the fixing bracket 12 in the air passage hole 11 of the frame 10 to transmit the pressing force is lifted. Press the falling member 40 to lower; The eccentric pivot shaft portion 33 protruding from the connecting portion 32 so as to be eccentric with the wing pivot shaft portion 31 of the air induction wing 30 in the pivot groove portion 41 formed in the middle of the elevating member 40 in the circumferential direction. ) Is inserted so that the eccentric rotational shaft portion 33 is rotated in the up and down directions by the movement of the elevating member 40 is raised and lowered; The outer circumference of the lifting member 40 is the outer circumference of the shaft groove hole 52 is installed so that the wing pivot shaft 31 is rotatable so that the locking jaw portion 34 of the air induction wing 30 is caught on the escape prevention jaw portion (51). A plurality of shaft grooves may be provided at the edges and fixed to the lower part of the temperature sensing cylinder 20 by the fastening means 60 while simultaneously providing the wing support member 50 having the lifting member movement space 53 with a plurality of equal intervals. 52, respectively, and the wing pivot shafts 31 fitted to each other are supported so that the wing pieces 35 of the air guide vanes 30 exposed to the outside are rotatable; The lower and lower member movement space 53 is provided according to the type of cooling and heating air introduced into the room by having a resilient member 70 for moving the elevating member 40 to move up when the pressing force is lost. It is to be automatically converted to the vertical direction or the horizontal direction.

Air Conditioning Diffuser, Air Conditioning Diffuser Wings, Self-Adjusting Diffuser

Description

Diffuser for air conditioning that air conditioning air supply direction is changed automatically}

1 is a longitudinal cross-sectional view of the diffuser in which the present invention is practiced;

2 is a cross-sectional view of the main portion of the present invention separated;

Figure 3 is a longitudinal cross-sectional configuration of the main part when supplying the cooling air of the present invention,

4 is a cross-sectional view taken along line X-X 'of FIG. 1;

5 is a sectional view taken along the line Y-Y 'of FIG.

6 is an exploded perspective view of the air induction blade according to the present invention;

Figure 7a is a cross-sectional view of the combination of the air induction blade of the present invention,

7B is a cross-sectional view taken along the line Z-Z 'of FIG. 7A;

8 is a sectional view showing the principal parts of the operation of the present invention;

9 is a plan sectional view in a heating air supply state according to the present invention;

10 is a sectional view showing the main parts of a heating air supply state of the present invention;

11 is a full sectional view of the diffuser showing a cooling air supply state of the present invention;

12 is an overall cross-sectional view of the diffuser showing a heating air supply state of the present invention.

Explanation of symbols on the main parts of the drawings

1: Air duct 10: Frame

11: air passage hole 12: fixing bracket

20: temperature sensing cylinder 21: wax

22: piston rod 23: pressure member

30: air induction wing 31: wing rotation shaft

32: connecting portion 33: eccentric rotational shaft

34: locking jaw 35: wing

40: lifting member 41: rotation groove

50: wing support member 51: separation prevention member

52: shaft groove 53: lifting member movement space

60: fastening means 70: elastic member

The present invention relates to an air-conditioning diffuser installed on the ceiling of a building to allow cooling and heating air to be supplied from an air conditioner to a room. More specifically, the air supply to the room is provided by a temperature of cooling air or heating air. The present invention relates to an air conditioner diffuser that is improved to automatically change direction.

In general, in the air conditioning of a building, cooling air is supplied to the room in summer and diffused air is supplied in the winter through a diffuser installed in the ceiling of the building.

In the room, the hot air is raised from the bottom to the upper side, and the cold air is conversely lowered upwards. Therefore, the cold air supplied from the diffuser to the room is preferably supplied to diffuse in the ceiling direction. It is desirable to be fed straight down the room.

When cold air is supplied to the ceiling and diffused convection under the room, the cooling of the room becomes efficient and the workers working under the diffuser do not shoot the cooling air directly. This is prevented beforehand.

In addition, since the heating air is supplied downward, the heating air is diffused from the lower part of the room and is diffused by the convection upward, thereby facilitating rapid heating of the entire room.

On the other hand, for the sake of understanding, the air supplied from the diffuser to the room to be supplied to be diffused in the ceiling direction is to be supplied in the horizontal direction, and to be supplied straight down from the diffuser is defined as being supplied in the vertical direction. .

Therefore, in the past, some diffusers provided cooling and heating air in the horizontal or vertical direction, but since most of the diffusers were operated manually, many diffusers installed in each room of the building were used during the winter and summer seasons. There was an uncomfortable and cumbersome problem that must be manipulated every time.

Therefore, recently, a diffuser that detects cooling and heating temperatures by using a temperature sensing cylinder using expansion and contraction of wax to change the blowing direction of the air supplied through the diffuser has been developed. In other words, it is not easy to change the air direction to the desired state or the like.

It is an object of the present invention to provide a diffuser for air conditioning in which the supply direction of air supplied to the room is automatically converted by the temperature of cooling air or heating air.

Another object of the present invention is to provide an air conditioning diffuser in which the operability for changing the air direction is smoothly performed.

The present invention for achieving the above object, has a through-hole through which air cooling and heating air is supplied from the air duct and has a frame fixed to the ceiling member and the wax filled by the temperature of the air passing through the air through-hole To inflate and deflate and cause the air induction vanes to be rotated by the operation of a temperature sensing cylinder with a piston rod; A pressure member coupled to the piston rod of the temperature sensing cylinder fixedly installed in the air passage hole of the frame to be fixed by a fixing bracket to press and lower the lifting member; The eccentric pivot shaft portion is inserted into the pivot groove portion formed in the circumferential direction in the middle of the elevating member so that the eccentric pivot shaft portion protruding from the connecting portion is eccentric with the wing pivot shaft portion of the air guide blade. Rotate up and down; At the outer side of the elevating member, a plurality of axial grooves are installed at the outer periphery of the outer circumferential edge of the shaft turning hole to be rotatably installed so that the locking jaw portion of the air induction blade is latched away from the jaw portion. The wing supporting member is fixed to the lower part of the temperature sensing cylinder by the fastening means, so that the wing pivot shafts respectively fitted to the plurality of shaft grooves are supported so that the wing pieces of the air induction blades exposed to the outside can be rotated; The lower and lower members of the movement space portion is characterized in that the elastic member is installed to move the lifting member is raised when the pressing force is lost.

 Rotating groove portion of the elevating member is formed on the upper surface of the lower body is characterized in that the upper body is configured to be fastened by a screw after the eccentric rotation shaft portion is coupled.

The wing support member is formed to be divided into upper, lower body and is characterized in that the wing rotating shaft is coupled to the shaft groove hole is configured to be fastened by a screw.

The fastening means is characterized in that the fastening hole formed in the upper portion of the wing support member and the bottom fastening portion of the temperature sensing cylinder screwed to the fastening hole.

The air guide vane is characterized in that the coupling portion is formed on both sides of the wing pivot shaft portion to provide a fitting groove, and the metal fitting is inserted into the fitting groove to be fixed by screws.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows the entire longitudinal cross-sectional view of the present invention, the diffuser of the present invention is provided with a temperature sensing cylinder 20 which is fixed by a fixing bracket 12 inside the air passage hole 11 of the frame 10 and And, wing support to support the air induction wing 30 while wrapping the elevating member 40 and the elevating member 40, the pressing member 23 is pressed by the pressing force of the temperature sensing cylinder (20) It is configured to have a member 50.

The diffuser is installed so that the frame 10 is fixed to the ceiling member 2, the air passing through the air (11) so that the cooling, heating air can be supplied from the air duct (1).

2 and 3, the temperature sensing cylinder 20 expands or contracts the volume of the wax 21 filled by the temperature of the air passing through the air passage hole 11.

That is, when the hot air is in contact with the temperature sensing cylinder 20, heat is transferred to the wax 21 and the piston rod 22 moves forward as the volume is expanded. When the heat retained by the 21 is lost, the volume is contracted so that the piston rod 22 can be moved to be inserted into the inside.

In the present invention, the piston rod 22 to be inserted is moved to be inserted by the elasticity of the elastic member 70 will be described later.

The temperature sensing cylinder 20 is already known components and the present invention is to use the known temperature sensing cylinder 20 to rotate the air induction wing 30.

Therefore, the temperature sensing cylinder 20 is installed to be fixed by the fixing bracket 12 in the air passage hole 11 of the frame 10, and the leg portion 12a of the fixing bracket 12 is the frame 10 The inner surface is fixed by a rivet or the like, and is fastened by fastening the fastening portion 24 of the temperature sensing cylinder 20 to the fastening hole 12b in the middle portion thereof (see FIG. 4).

The piston rod 22 of the temperature sensing cylinder 20 is coupled to fit the pressing member 23 for transmitting the pressing force is configured to press down the lifting member 40.

The eccentric pivot shaft portion 33 protruding from the connecting portion 32 so as to be eccentric with the wing pivot shaft portion 31 of the air induction wing 30 in the pivot groove portion 41 formed in the middle of the elevating member 40 in the circumferential direction. ) Is inserted so that the eccentric rotation shaft portion 33 can be rotated in the up and down directions by the movement of the elevating member 40 is raised and lowered, the rotation groove 41 of the elevating member 40 Is formed on the upper surface of the lower body 42 is coupled to the eccentric pivot shaft portion 33 to fasten the upper body 42 'by the screw 43.

In addition, outside the elevating member 40, the shaft groove hole 52 is installed so that the wing pivot shaft 31 is rotatable so that the locking jaw portion 34 of the air induction wing 30 is engaged with the release prevention jaw portion (51). A plurality of shaft grooves are provided on the outer circumferential edge at the same time and fixed to the lower part of the temperature sensing cylinder 20 by the fastening means 60 while simultaneously providing the wing support member 50 having the lifting member movement space portion 53 at equal intervals. The wing pivot shafts 31, which are assembled to be fitted to the respective 52, are supported to be rotatably mounted to the wing pieces 35 of the air guide vanes 30 exposed to the outside.

The wing support member 50 is formed to be divided into upper and lower bodies 54 and 54 ', and is coupled to the shaft groove hole 52 by a screw 55 after coupling the wing pivot shaft 31.

And the fastening means 60 is to be fastened to the fastening hole 61 formed in the upper portion of the wing support member 50 and the lower fastening portion 62 of the temperature sensing cylinder 20 screwed to the fastening hole 61. Standing, to fix the wing support member 50 does not flow.

In the present invention, since the wing support member 50 only needs not to move, although not illustrated in the drawing, the wing support member 50 may be fixed to the frame 10 by using a separate bracket.

On the other hand, in the lower portion of the elevating member movement space portion 53 of the wing support member 50, an elastic member 70 for moving the elevating member 40 to be raised when the pressing force of the temperature sensing cylinder 20 is lost It is configured to be installed.

The elastic member 70 is preferably used to be formed of a coil spring, it is installed to be fitted to the lifting guide shaft (56).

The lifting guide shaft 56 is assembled to fit in the guide hole 44 of the lifting member 40 to serve to guide the lifting member 40 to move in the vertical direction.

5 shows a state in which a plurality of air guide vanes 30 are installed at equal intervals in the circumferential direction of the elevating member 40 and the wing support member 50.

The air guide vanes 30 may be integrally formed of a plastic-like material, but as shown in FIG. 6, the wing pieces 35 may be separately manufactured by using a metal plate.

In detail, as shown in FIGS. 7A and 7B, the coupling part 36 is formed at the tip portion of the blade pivot shaft 31 so that the fitting groove 37 is provided, and the fitting groove 37 is formed of a metal material. It is configured to be formed by inserting the blade piece 35 is fixed with a screw 38.

8 is a view illustrating the working state of the present invention, the wax 21 of the temperature sensing cylinder 20 has a state in which the volume is completely contracted at 17 ℃ and an expanded state at 27 ℃ do.

Therefore, when the cooling air is supplied, the piston rod 22 enters the inside of the temperature sensing cylinder 20 and the lifting member 40 maintains the raised state.

In addition, the wing piece 35 of the air induction wing 30 is assembled to be set to have an inclined state as shown in the solid line.

Therefore, in the state in which cooling air is supplied, the cooling air is guided by the blade piece 35 to be blown in the inclined direction and supplied to the room.

However, when the heating air is supplied, the temperature of the heating air is transmitted to the temperature sensing cylinder 20 and expanded as the temperature of the wax 21 is raised.

When the wax 21 is expanded, the piston rod 22 is pushed out so that the pressing member 23 presses the lifting member 40 as it moves forward.

Therefore, the elevating member 40 is moved downward to move the eccentric pivot shaft portion 33 of the air induction wing 30 is rotated from the "A" point to the "B" point in the downward direction by rotating the wing The shaft portion 31 is rotated so that the blade piece 35 is rotated in a vertical state as shown in the imaginary line.

At this time, the lifting member 40 is moved downward to be in a state of being rotated slightly in the circular direction as shown in FIG. 9, but the eccentric rotation shaft 33 is not separated from the rotation groove 41.

Accordingly, the heating air passing through the air passing hole 11 of the frame 10 is blown in the vertical direction so that the blade pieces 35 of all the air guide vanes 30 are rotated in the vertical direction, and the heating air is blown in the vertical direction. It is supplied, and this state is maintained as long as heating air is continuously supplied.

And while the heating air continues to supply the elevating member 40 is maintained in a lowered state, so the elastic member 70 is in a compressed state as shown in FIG.

In this state, when the cooling air is supplied, the heat retained by the wax 21 of the temperature sensing cylinder 20 is deprived, and the volume shrinks as the temperature of the Wans 21 decreases.

When the wax 21 contracts, the pressing force for pressing the piston rod 22 is lost, and thus, the pressing member 23 and the piston rod 22 including the elevating member 40 in addition to the elasticity of the elastic member 70. ) Is moved upward.

Therefore, in FIG. 8, the eccentric pivot shaft portion 33 of the air guide vane 30 is rotated from the "B" point to the "A" point in the upper direction, so that the wing pivot shaft 31 is rotated so that the wing piece 35 is rotated. It is rotated to be inclined as shown in the solid line state.

Therefore, the cooling air is guided to the blade piece 35 rotated obliquely and is blown in the inclined direction to be supplied to the room.

As the cooling air is inclined and blown, the wind blows against the inner circumferential surface of the frame 10 and becomes a whirlwind as shown in FIG. 11.

And when the apparatus of the present invention is arranged to be disposed below the frame 10, the cooling air is blown in the horizontal direction if the cooling air is not obliquely hit by the inner peripheral surface of the frame 10.

FIG. 12 shows that the wing pieces 35 of the air induction vehicle 30 are rotated in a straight state when the heating air is supplied, and the heating air is supplied in the vertical direction.

As described above, the present invention provides an air conditioning diffuser in which the supply direction of the air supplied to the room is automatically converted by the temperature of the cooling air or the heating air, so that the air direction does not need to be changed every season. It has an effect.

Claims (5)

 It has an air passage hole 11 through which the cooling and heating air is supplied from the air duct 1, and has a frame 10 fixed to the ceiling member 2, and at the temperature of the air passing through the air passage hole 11. The wax 21 filled by the expansion and contraction and the air induction wing 30 is rotated by the operation of the temperature sensing cylinder 20 having the piston rod 22; The pressure member 23 coupled to the piston rod 22 of the temperature sensing cylinder 20 installed to be fixed to the fixing bracket 12 in the air passage hole 11 of the frame 10 to transmit the pressing force is lifted. Press the falling member 40 to lower; The eccentric pivot shaft portion 33 protruding from the connecting portion 32 so as to be eccentric with the wing pivot shaft portion 31 of the air induction wing 30 in the pivot groove portion 41 formed in the middle of the elevating member 40 in the circumferential direction. ) Is inserted to rotate the eccentric rotation shaft portion 33 in the up and down directions by the movement of the elevating member 40 is raised and lowered; The outer circumference of the lifting member 40 is the outer circumference of the shaft groove hole 52 is installed so that the wing pivot shaft 31 is rotatable so that the locking jaw portion 34 of the air induction wing 30 is caught on the escape prevention jaw portion 51. A plurality of shaft grooves may be provided at the edges and fixed to the lower part of the temperature sensing cylinder 20 by the fastening means 60 while simultaneously providing the wing support member 50 having the lifting member movement space 53 with a plurality of equal intervals. 52, the blade pivot shafts 31 respectively fitted to each other are supported to allow the blade pieces 35 of the air guide vanes 30 exposed to the outside to be rotatable; The heating and cooling air supply direction is automatically changed, characterized in that the elastic member 70 is installed below the elevating member movement space 53 to move the elevating member 40 upward when the pressing force is lost. Air conditioning diffuser. The rotating groove 41 of the elevating member 40 is formed in the upper surface of the lower body 42, the upper body 42 'is screwed after the eccentric pivot shaft 33 is engaged with the screw 43. Air-conditioning diffuser is automatically converted to the heating and cooling air supply direction, characterized in that configured to be fastened by. The method of claim 1, wherein the wing support member 50 is formed to be divided into upper and lower body (54, 54 ') to the screw shaft 55 after the wing pivot shaft portion 31 is coupled to the shaft groove (52) Air-conditioning diffuser for automatically switching the heating and cooling air supply direction, characterized in that configured to be fastened by. According to claim 1, The fastening means 60 is a lower fastening portion of the fastening hole 61 formed in the upper portion of the wing support member 50 and the temperature sensing cylinder 20 is screwed to the fastening hole 61 ( The air conditioner diffuser is automatically converted to the heating and cooling air supply direction characterized in that the fastening. According to claim 1, The air induction blade 30 is provided with a fitting groove portion 37 by forming a coupling portion 36 in the tip end portion of the wing pivot shaft 31, and the blade piece 35 in the fitting groove portion 37 The air-conditioning diffuser is automatically converted to the heating and cooling air supply direction, characterized in that configured to be formed by inserting the fixed with a screw (38).

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