KR20150052103A - Electric variable-air-volume diffuser - Google Patents

Abstract

A variable air volume (VAV) diffuser includes a diffuser housing configured to couple to a supply air duct. The diffuser housing has an outlet for the discharge of supply air into the chamber from the supply air conduit. The VAV diffuser may further include a support structure attached to the diffuser housing and a flow controller for varying the amount of supply air exiting through the outlet. The VAV diffuser may further include an electrical actuator mounted to the support structure for moving the flow controller to vary the amount of supply air. With the diffuser housing coupled to the supply air conduit and the support structure attached to the diffuser housing and also with the flow controller held within the diffuser housing, the electric actuator can be accessible from the side and removed from the diffuser housing have.

Description

[0001] ELECTRIC VARIABLE-AIR-VOLUME DIFFUSER [0002]

The present invention relates generally to variable air diffusers for regulating air flow, and more particularly to variable air diffusers driven by an electric motor for varying the amount of supply air in a space.

Variable-air-volume diffusers (VAVs) have been used for various purposes. One of the most common applications is for use in heating, ventilating and air conditioning (HVAC) systems to deliver feed air to a space where codification is required. In response to thermal loading (which depends on a number of factors and which varies considerably with time and space), the VAV diffuser adjusts the amount of supply air exiting the selected space to achieve the desired conditioning effect.

An example of controlling the volume flow rate of air conditioning air can be found in US Pat. No. 6,176,777 to Smith et al., Which discloses a self-modulating diffuser for air conditioning systems. Another example is Dozier et al., U.S. Patent No. 5,860,592, which discloses a VAV diffuser and method with independent ventilation air assemblies. Other examples of air diffusers or VAV air diffusers are disclosed in U.S. Patent Application Publication No. 2006/0292977 to Caldwell et al., Which discloses an electrically powered air diffuser, and U.S. Patent No. 6,997,799 to Mrozek et al., Which discloses a damper including a stepper motor No. 6,224,481 to McCabe, which discloses a butterfly blade damper operated with a power control leadscrew.

Current VAV diffusers can adjust the amount of supply air, but have disadvantages in terms of maintenance serviceability and / or energy efficiency and / or condensate management. In order to access the interior for maintenance services, current VAV diffusers generally need to be separated or disassembled in an HVAC system. For example, in order to repair or replace an actuator or motor, current VAV diffusers may need to separate the entire VAV diffuser from the HVAC system or disassemble most components from the VAV diffuser. This process increases downtime and maintenance costs. In addition, current VAV diffusers can not be used to exhaust feed air at low temperatures without the formation of a barrel.

In view of the above, it is desirable to provide an improved pressure control valve or assembly that overcomes at least some of the aforementioned problems.

The information described in this background section is merely intended to increase the understanding of the general background knowledge of the present invention and is not intended to be construed as an admission that this information forms a prior art known to the ordinary artisan, It should not be.

The various aspects of the present application are intended to provide a variable air volume (VAV) diffuser that provides many advantages, including ease of serviceability, energy efficiency, and / or condensate management.

One aspect of the present application is to provide a VAV diffuser comprising a variable air diffuser wherein the variable air diffuser is configured to be coupled to a supply air conduit and having an outlet for discharge of supply air into the chamber from the supply air conduit A diffuser housing; A support structure attached to the diffuser housing; A flow controller for varying the amount of supply air exiting through the outlet; And an electrical actuator mounted on the support structure for moving the flow controller to change the amount of supply air, wherein the diffuser housing is coupled to the feed air conduit, the support structure is attached to the diffuser housing, With the flow controller held within the diffuser housing, the electric actuator can be accessible from the side and removed from the diffuser housing.

A flow controller may be movably mounted on the support structure. The flow controller may be pivotably mounted on the support structure by a hinge. The flow controller may comprise a plurality of blades, each of which may be movably mounted on a support structure. The flow controller may include four blades, each of which may be movably mounted on a support structure.

The electric actuator may include a stepper motor. The electrical actuator may be removably mounted on a bracket attached to the support structure.

The variable air diffuser may further include a link assembly connecting the flow controller to the electrical actuator, wherein the electrical actuator may be configured to rotate the flow controller around the hinge. The variable air diffuser may further include a plurality of link assemblies, each link assembly connecting each blade of the plurality of blades to an electric actuator.

A shaft hole and a link hole may be formed in the support structure. The electric motor may include a threaded shaft extending substantially through the shaft hole of the support structure. The link assembly includes a hub screwed onto the threaded shaft of the electric actuator, a first link attached to the hub at one end and extending downwardly through a link aperture of the pile structure, a first link rotatably mounted to the support structure at one end A second link, a third link rotatably mounted to the flow controller at one end, and a fourth link, one end of the fourth link being rotatably connected to the other end of the first link, And the other end of the fourth link is rotatably connected to the other end of the second and third links. The hub may be operably coupled to the threaded axis of the electrical actuator. The support structure may be provided with a mounting hole for mounting and removing the electric actuator.

The variable air diffuser may further include a guide attached to the support structure and extending substantially upward to prevent rotation of the flow controller.

The electric actuator may comprise a screw shaft extending substantially upward and the flow controller may be provided with a shaft hole and a guide hole and the flow controller may be screwed with the screw shaft of the electric actuator through the shaft hole, And can be slidably engaged with the guide through the guide hole.

The flow controller may be a disk.

The variable air diffuser may further include an exterior plate that can be removably attached to the support structure. One edge of the exterior plate can be rotatably hinged to a bracket attached to the support structure and the opposite edge of the exterior plate can be releasably secured to the support structure.

The variable air diffuser may further comprise an insulating layer that may be disposed on at least a portion of the flow controller.

The variable air diffuser may further comprise a sensor for measuring the room temperature, the temperature of the supply air, or the flow rate of the supply air.

The diffuser housing may include a diffuser neck configured to be coupled to the feed air conduit and a diffuser cone configured to discharge the feed air at an angle to the downward direction and wherein the diffuser neck and diffuser cone are integrally formed, Lt; / RTI >

Another aspect of the invention is a diffuser housing formed to be coupled to a supply air conduit and having a discharge port for discharge of supply air into the chamber from the supply air conduit; A support structure attached to the diffuser housing; A plurality of blades movably mounted on the support structure for varying the amount of feed air exiting through the outlet; And a link assembly connecting the plurality of blades to the electric actuator, wherein the diffuser housing is coupled to the feed air conduit, the support structure is attached to the diffuser housing and is also connected to the link assembly , The electric actuator is accessible from the side and can also be removed from the diffuser housing.

Yet another aspect of the invention is a diffuser housing formed to be coupled to a supply air conduit and having a discharge port for discharge of supply air from the supply air conduit into the chamber; A support structure attached to the diffuser housing and formed with mounting holes; A flow controller for varying the amount of supply air exiting through the outlet; A guide attached to the support structure and extending substantially upward to prevent rotation of the flow controller; And an electrical actuator mounted on the support structure through the mounting hole for moving the flow controller to change the amount of supply air, the diffuser housing being coupled to the supply air conduit, With the structure attached to the diffuser housing and with the flow controller held within the diffuser housing, the electric actuator can be accessible from the side through the mounting holes of the support structure and also removed from the diffuser housing of the support structure .

The method and apparatus of the present invention have other features and advantages which are apparent from or elucidated with reference to the accompanying drawings and the following detailed description which follows, and the accompanying drawings and detailed description are to be regarded as illustrative of the principles of the invention .

In the drawings, like numbers refer to like elements throughout. Similar numbers with other letters after the letters indicate other examples of similar elements. The drawings illustrate, by way of example and not limitation, various embodiments generally described herein.
BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 a shows a cross-sectional view of an exemplary fully open VAV diffuser according to the present application.
Figure 1B shows a cross-sectional view of an exemplary partially open VAV diffuser according to the present application.
Figure 1C shows a cross-sectional view of an exemplary closed VAV diffuser according to the present application.
Figure 2a shows a cross-sectional view of another fully open VAV diffuser according to the present application.
Figure 2B shows a cross-sectional view of another partially open VAV diffuser according to the present application.
2C shows a cross-sectional view of another exemplary closed VAV diffuser according to the present application.
Figure 2D illustrates an exemplary room air induction passage that may be used with the exemplary VAV diffuser of Figure 2A.
Figure 3 shows a prototype of an exemplary VAV diffuser with an insulating layer according to the present application.
4A shows a perspective view of an exemplary VAV diffuser mounted on a ceiling according to the present application.
Figure 4b shows a perspective view of an exemplary VAV diffuser mounted on a ceiling according to the present application and illustrating the operation of opening the exterior plate.
Figure 4c shows a perspective view of an exemplary VAV diffuser mounted on a ceiling according to the present application, illustrating the act of disassembling the actuator.

Reference will now be made to the various embodiments of the invention (s), examples of which are illustrated in the accompanying drawings and described below. While the present invention will be described in conjunction with exemplary embodiments, it is to be understood that the description is not intended to limit the invention (s) to these exemplary embodiments. On the contrary, the invention is intended to cover various alternatives, modifications, equivalents, and other embodiments, which may be included within the spirit and scope of the invention as defined by the appended claims, It is intended.

Referring to FIGS. 1A-1C, an exemplary variable air volume (VAV) diffuser 100 is shown that is fully open, partially open, and fully closed, respectively. The VAV diffuser 100 may be used to regulate the air supply to the selected space. For use in commercial buildings, the VAV diffuser 100 is typically mounted on the ceiling. In various embodiments, the exemplary VAV diffuser 100 generally includes a diffuser housing 102 configured to be coupled to a feed air conduit. The diffuser housing 102 has an outlet for discharging the supply air from a supply air conduit into a space such as a room where heating or air conditioning is required. The exemplary VAV diffuser 100 may also include a support structure 104 attached to the diffuser housing 102 and a flow controller 106 for varying the amount of feed air exiting through the vent. In various embodiments, the support structure 104 may serve as a diffuser plate. The exemplary VAV diffuser 100 may further include an electrical actuator 108 that is removably mounted on the pile structure 104. The electrical actuator 108 provides a driving force to move the flow controller 106 to vary the amount of supply air. The exemplary VAV diffuser 100 is configured such that the diffuser housing 102 is coupled to the feed air conduit and the support structure 104 is affixed to the diffuser housing 102 and also the flow controller 106, The electric actuator 108 is configured such that the electric actuator 108 is accessible to the room (i.e., accessible from the room) and can be removed from the diffuser housing 102 while the electric actuator 108 is held inside the diffuser housing 102.

The diffuser housing 102 may include a diffuser neck 110 for coupling to a respective feed air conduit and a diffuser cone 112 for discharging feed air. The diffuser neck 110 and the diffuser cone 112 may be formed separately from each other and then joined together, and the diffuser neck and diffuser cone may be monolithically or integrally formed, for example, by die-forming a metal sheet . Instead of directing the supply air downwardly, the diffuser cone 112 may cause the delivered supply air to flow away from the VAV diffuser 100 at an angle. The feed air discharged in this way mixes with the room air before progressively descending to promote the Coanda effect. The shape and size of the diffuser housing 102, diffuser neck 110, and diffuser cone 112 may vary according to the present application. Generally, the diffuser housing 102 has a centerline or center axis A, the centerline or central axis of which extends when the exemplary VAV diffuser 100 is mounted to the ceiling in a substantially vertical direction. In various embodiments, the diffuser cone 112 may have a square cross section at the opening.

1A-1C, the support structure 104 may be attached to the diffuser housing 102 by mechanical fasteners, such as one or more bolts 114 or rivets and / or other suitable fastening means. The support structure 104 may be attached to the diffuser housing 102 by other suitable means, such as welding, gluing or other suitable means. The support structure 104 may be circular, polygonal, or any other suitable shape. In some cases, where the support structure 104 is rectangular or square, four bolts 114 may be used, with one bolt positioned near one corner of the rectangular or square support structure 104. The support structure 104 may have a shaft hole 116 and one or more link holes 118 formed therein. In addition, the support structure 104 may be formed with a plurality of holes or nozzles through which supply air can pass to direct room air into the area. These features and actions are indicated by dotted arrow lines in Fig.

In various embodiments, the flow controller 106 is movably mounted on the support structure 104. In particular, the flow controller 106 may be pivotably mounted to the support structure 104 by a mechanical fastener such as a hinge 102. The flow controller 106 may be a vane, a blade, a flap, or the like. The flow controller 106 may comprise a plurality of vanes, blades or flaps, or a combination thereof. In some instances where the support structure 104 is a polygon such as a square, the flow controller 106 is preferably mounted near the edge of the polygon support structure 104. For example, the flow controller 106 may include four blades, each of which is pivotally mounted near one edge of the square support structure 104. The flow controller 106 may be controlled to move to a fully open position as shown in Figure 1A and a fully closed position as shown in Figure 1C. The flow controller 106 may also be controlled to move to any intermediate position as shown in Figure 1B, i.e. between the fully open position and the fully closed position, to change the flow or amount of feed air to be vented.

Continuing to refer to FIGS. 1A-1C, in various embodiments, the electrical actuator 108 may be mounted on the support structure 104. Preferably, the electrical structure 108 can be mounted on the side of the support structure 104 by a mechanical fastener so that the electrical actuator 108 is easily accessible and readily removable. For example, the electrical actuator 108 may be removably secured to the mounting portion 122. The mounting portion 122 may be attached or secured to the support structure 104 at one end, e.g., by welding. The other end of the mounting portion 122 may be inclined and may have a screw hole for receiving a screw for mounting the electric actuator 108. [ The mounting portion 122 may be a bracket. A plurality of, for example, four, mounting portions 122 may be used to mount the electrical actuator 108 to the support structure 104 to stabilize the electrical actuator 108 and reduce vibration.

In various embodiments, the electrical actuator 108 includes a motor 124 and a screw shaft 126 extending outwardly therefrom. The motor 124 may be a stepper motor. Since the stepper motor can be commanded to move and maintain in one of the equally divided steps, a feedback sensor may not be needed if such a stepper motor is used. When the electrical actuator 108 is mounted to the support structure 104, the screw shaft 126 may extend through the shaft bore 116 formed in the support structure 104. The support structure 104 and the shaft bore 116 are configured such that the electrical actuator 108 is positioned substantially along the centerline or center axis A of the diffuser housing 102 and the VAV diffuser 100 The threaded shaft 126 extends substantially upwardly through the shaft bore 116 formed in the support structure 104. As shown in Fig. The screw shaft 126 may be coupled with the flow controller 106 through a link assembly.

For example, FIGS. 1A-1C illustrate an exemplary link assembly 128 including a hub 130. FIG. In some cases, the hub 130 may be provided with a screw hole in which the hub 130 is screwed with the screw shaft 126 of the electric actuator 108. [ In other cases, a through hole may be formed in the hub 130, and a screw shaft 126 of the electric actuator 108 may extend through the through hole. In this case, a nut 140 may be used to engage the screw shaft 126 of the hub 130 and the electric actuator 108. The nut 140 may be attached to the hub 130, for example, by welding, or may be integrally formed with the hub 130 or integrally.

The exemplary link assembly 128 may further include a first link 132, a second link 134, a third link 136, and a fourth link 138. In various embodiments, the first link 132 may be attached to the hub 130 at one end, for example, by welding or suitable mechanical fasteners, and may be passed through a link hole 118 formed in the pile organizer 104 Can be extended downward. The second link 134 may be rotatably mounted on the support structure 104 at one end and the third link 136 may be rotatably mounted to the flow controller 106 at one end. The first link 132 may be connected to the second link 134 and the third link 136 by a fourth link 138. For example, one end of the fourth link 138 may be rotatably connected to the other end of the first link 132, and the opposite end of the fourth link 138 may be connected to the second link 134 and the third link 138 136 at the other end. A second link 134 and a third link 136 are rotatably mounted and a suitable element for rotatably connecting the first link 132 to the second link 134 and the third link 136 Or mechanism may include a hinge, a bearing, a pin, a rivet or a bracket.

It will be appreciated that the configuration of the exemplary link assembly 128 shown in FIGS. 1A-1C is illustrative only and is not limiting in any way. The exemplary link assembly 128 may not include four links or may include more than four links. The shape, dimensions, placement or mounting of these links may also vary according to the present application. For example, the link may be a strip, slab, stick, bar, rod or any other suitable shape. The link may be made of sheet metal, and may be formed of plastic or any other suitable material. It will be appreciated that any suitable assembly for coupling the flow controller 106 and the actuator 108 together is within the scope of the present application.

Through the exemplary link assembly 128, the actuator 108 moves the flow controller 106 to another position to vary the amount of air supplied to any room or room, depending on the thermal load. The actuator 108 rotates the screw shaft 126 in one direction so that the hub 130 moves along the axis 126 to open the VAV diffuser 100 so that a greater amount of supply air is discharged. And moves upward. The first link 132 of the link assembly 128 is attached to the hub 130 so that the first link 132 moves upward with the hub 130 and pulls the fourth link 138 upward. In response to this upward motion, the fourth link 138 rotates and at the same time pulls the second link 134 and the third link 136 inwardly. As a result, the third link 136 rotates or draws the flow controller 106 away from the diffuser housing 102, or in particular away from the sidewalls of the diffuser cone 112. The flow controller 106 is rotated about the hinge 120 when the flow controller 106 is hingedly connected to the support structure 104 or one edge of the support structure 104. Accordingly, the VAV diffuser 100 is opened, and a larger amount of supply air can be discharged into the space or the room. This opening operation is shown in Fig.

Similarly, to close the VAV diffuser 100, the actuator 108 rotates the screw shaft 126 in the opposite direction so that the hub 130 and the first link 132 move downward along the axis 126 do. The first link 132 pulls the fourth link 138 downward. In response to this downward movement, the fourth link 138 rotates and at the same time pushes the second link 134 and the third link 136 outwardly. As a result, the third link 136 rotates or pushes the flow controller 106 toward the diffuser housing 102, or in particular toward the sidewall of the diffuser cone 112, to close the VAV diffuser 100. When the flow controller 106 is hingedly connected to the support structure 104 or one edge of the support structure 104, similar to the case of opening the VAV diffuser 100, the flow controller 106 controls the hinge 120, respectively. Thus, the supply air will never or almost never be discharged into the space or the room. This closing operation is shown in FIG.

In addition, through the exemplary link assembly 128, the actuator 108 may cause the flow controller 106 to be in any intermediate position between the open and closed positions, depending on the thermal load. Depending on the initial position of the flow controller 106, the actuator 108 may rotate the screw shaft 126 in a direction toward the fully open position or in a direction opposite the closed position until a desired supply air quantity is obtained . The flow controller 106 in the intermediate position is shown in Figure IB.

In various embodiments, the exemplary VAV diffuser 100 may include a plurality of link assemblies 128, each link assembly corresponding to one vane or blade. For example, if the flow controller 106 comprises four blades, the exemplary VAV diffuser 100 may include four link assemblies 128. [ Each link assembly 128 corresponds to one blade that is rotatably mounted on the support structure 104 and moves each blade to another position to vary the amount of air supplied. In this configuration, the support structure 104 may be provided with a plurality of link holes 118 for receiving the respective first links 132. [

Referring now to Figures 2A-2C, it is shown that another exemplary VAV diffuser 200 is in an open position, an intermediate position, and a closed position, respectively. The exemplary VAV diffuser 200 generally includes a diffuser housing 102, a support structure 202, a flow controller 204 and an electrical actuator 108, similar to the exemplary VAV diffuser 100. The support structure 202 may be attached to the diffuser housing 102. The electrical actuator 108 can be removably mounted on the support structure 202 and moves the flow controller 204 to change the amount of supply air exiting through the outlet. Exemplary VAV diffusers 200 may be configured such that the diffuser housing 102 is coupled to the feed air conduit and the support structure 202 is coupled to the diffuser housing 102. In various embodiments, And is configured such that the electric actuator 108 is accessible at the front and is also removable from the diffuser housing 102 with the flow controller 204 held within the diffuser housing 102 .

Similar to support structure 104, support structure 202 may be circular, polygonal, or any other suitable shape and may be attached to diffuser housing 102 in the same or similar manner. Unlike the support structure 104 in which the shaft hole 116 and the one or more link holes 118 are formed, a mounting hole 206 may be formed in the pile structure 202, and the electric actuator 108 may be formed in the mounting hole To the support structure 202 and may also be removed from the support structure 202 after the thread is unscrewed. The support structure 202 and the mounting hole 206 are configured such that the electric motor 108 is positioned substantially along the centerline or center axis A of the diffuser housing 102 and the VAV diffuser 200 Is mounted on the ceiling, the screw shaft 126 extends substantially upward.

In various embodiments, the flow controller 204 is movably engaged with the threaded shaft 126 of the electrical actuator 108 or the electrical actuator 108. The flow controller 204 may be a disk, and may have a circular, polygonal, or any other suitable shape. In some cases, a threaded bore may be formed in the flow controller 204, which causes the flow controller 204 to thread with the threaded shaft 126 of the electric actuator 108. In other cases, a through hole may be formed in the flow controller 204, and a screw shaft 126 of the electric actuator 108 extends through the through hole. In this case, a nut 140 may be used to engage the threaded shaft 126 of the flow controller 204 and the electrical actuator 108. The nut 140 may be attached to the flow controller 204, for example by welding, or may be formed integrally or integrally with the flow controller 204. A guide hole 208 may be formed in the flow controller 204.

In various embodiments, the exemplary VAV diffuser 200 may further include a guide 210, one end of which is attached to the support structure 202 to prevent rotation of the flow controller 204 . The size and shape of the guide 210 may vary according to the present application. For example, guide 210 may be a rod having a circular or polygonal cross-section. The guide 210 extends substantially upwardly through a guide hole 208 formed in the flow controller 204 and is slidably engaged with the flow controller 204. When the screw shaft 126 rotates, the guide 210 prevents the flow controller 204 from rotating with the screw shaft 126. As a result, the flow controller 204 moves up or down along the screw shaft 126.

In order to open the exemplary VAV diffuser 200, the actuator 108 rotates the screw shaft 126 in one direction, and, until it reaches the fully open position as shown in FIG. 2A, the flow controller 204 ) Away from the diffuser neck portion 110. As shown in FIG. To close the exemplary VAV diffuser 200, the actuator 108 is caused to rotate the screw shaft 126 in the opposite direction, and thus, until it reaches the closed position as shown in Figure 2c, The flow controller 204 is driven upwardly in the direction of the diffuser neck 110 until the flow controller 204 is closed. Depending on the change in thermal load, the flow controller 204 may be controlled to obtain a desired amount of feed air, and may be in an intermediate position (such as that shown in Figure 2B) between the fully open position and the closed position.

Exemplary VAV diffusers 100 and 200 include one or more sensors 144 that measure room air temperature, supply air temperature, supply air flow rate, or other parameters, and movements of the flow controller based on measurements by the sensors 144. [ And a control system for controlling the control unit. The sensor 144 and the control system may be mounted inside or outside the diffuser housing 102. For example, the supply air temperature sensor 144 may be mounted to the supply air conduit or the diffuser neck 110 of the diffuser housing 102. The room air temperature sensor 144 may be mounted externally, such as a wall of a room, and may also be electrically connected to the control system. The room air temperature sensor 144 may be mounted inside the room air flow path or the room air induction path 212 as shown in FIGS. 2A to 2C.

The room air induction passage 212 is configured to direct a certain amount of room air flow over the room air temperature sensor 144 to ensure an accurate measurement of the room air temperature. The room air induction passage 212 may be disposed or made on the diffuser housing 102, support structure 104, or other suitable location, as long as it directs room air over the sensor 144. For example, in Figures 2A-2C, the room air induction passage 212 formed on the support structure 104 is shown. In addition, the room air induction passage 212 may be included in any of the appropriate VAV diffusers, such as the exemplary VAV diffuser 100 shown in FIG. 1A and the exemplary VAV diffuser 200 shown in FIG. 2A.

The configuration of the room air induction passage 212 may vary depending on the present application. 2a shows an atmospheric air induction passage 212 that includes one or more induction nozzles formed on a support structure 104. As shown in FIG. The one or more induction nozzles may be configured to cause the feed air or the main air to exit the nozzle in a direction substantially parallel to the support structure 104 and thereby effectively direct room air or secondary air into the area or onto various sensors . Additionally, one or more induction nozzles may be angled relative to one another.

Another example of the room air induction passage 212 is shown in FIG. 2D. As shown, the room air induction passage 212 includes two C-channels 212a and 212b facing each other. The C-channel 212a extends substantially from one side to the other and has an opening at one end. The C-channel 212b is relatively short and is located near the opening at the end of the C-channel 212a. The induced air flows through the opening and onto the sensor (if present).

As shown in the figure, the exemplary VAV diffusers 100, 200 may further include an exterior plate 142. The exterior plate 142 may be attached to the support structure 104 or the diffuser housing 102. One edge of the exterior plate 142 may be hinged or hinged to a bracket or a plurality of brackets 302 that are attached to the pile structure 104, . The other edge or opposite edge of the exterior plate 142 may be releasably attached to the support structure 104 by a bracket, hook, loop or ring 304 that is attached, for example, on the support structure 104. For detachable attachment of the outer plate 142, other mechanisms, such as a magnet or snap fit, may be used.

In various embodiments, the exemplary VAV diffusers 100, 200 may further include an insulating layer 306 disposed on the flow controller 106 and / or the support structure 104. Generally, the insulating layer 306 is disposed on the side facing the feed air conduit and along the flow path of the feed air to be discharged. The insulating layer may cover the entire surface of the flow controller 106 and / or the entire surface of the pile structure 104. In addition, the insulating layer may cover only one portion of the flow controller 106 and / or only a portion of the pile structure 104. The insulating layer 306 may comprise an absorber capable of absorbing sound, vibration or condensate. The insulating layer 306 may also include other materials that can eliminate or reduce other undesirable effects. In some cases, the insulating layer 306 may comprise a foam sheet and / or other suitable insulating means.

Typically, the feed air to cool the commercial building is above about 55 [deg.] F. This is because the lower temperature of the feed air can generate condensate or sediment that can worsen the VAV diffuser. By isolating the condensate-absorbing insulating layer 306, the exemplary VAV diffusers 100, 200 can be used to extract a small amount of supply air at low temperature to achieve the same conditioning effect. In this way, the exemplary VAV diffusers 100 and 200 can save energy because less energy is required to discharge a small amount of supply air.

Referring now to Figures 4A-4C, there is shown an operation for repairing or replacing an actuator in an exemplary VAV diffuser according to the present application. This is an example showing the easy accessibility and uncomfortable serviceability of an exemplary VAV diffuser. As shown, disassembling the actuator basically involves two steps: separating one edge of the outer plate 142 at the support structure 104 and disassembling or unscrewing the actuator 108. Replacement with a new actuator can be accomplished simply by reversing these two steps. Whether the actuator is disassembled or replaced, there is no need to disassemble the exemplary VAV diffuser from the ceiling or the supply air duct. Moreover, there is no need to separate or disassemble other components from the exemplary VAV diffuser. Thus, time is saved, costs are reduced, and no special training is required.

It will be understood that, for convenience of description and exact definition of the appended claims, the terms "above" or "below", "inwardly" or "outwardly" Is used to describe the position of the feature.

The foregoing description of specific exemplary embodiments of the invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and obviously, many modifications and variations are possible in light of the above teachings. Exemplary embodiments are chosen and described in order to explain what principles of the present invention and its practical use are capable of making and using various exemplary embodiments of the present invention and various alternatives and modifications thereof . The scope of the invention is defined by the claims appended hereto and equivalents thereof.

100 variable air volume (VAV) diffuser
102 Diffuser Housing
104 support structure
106 flow controller
108 Electric Actuator

Claims (22)

As variable air diffusers,
A diffuser housing formed to be coupled to the feed air conduit and having an outlet for the discharge of feed air into the chamber from the feed air conduit;
A support structure attached to the diffuser housing;
A flow controller for varying the amount of supply air exiting through the outlet; And
An electrical actuator mounted on the support structure for moving the flow controller to change the amount of supply air,
Wherein the diffuser housing is coupled to the supply air conduit and the support structure is attached to the diffuser housing and the flow controller is held within the diffuser housing, Wherein said diffuser housing is removable from said diffuser housing. The method according to claim 1,
The flow controller being movably mounted on the support structure. The method according to claim 1,
The flow controller being pivotally mounted by a hinge on the support structure. The method according to claim 1,
Wherein the flow controller includes a plurality of blades, each blade being movably mounted on the support structure. The method according to claim 1,
Wherein the flow controller includes four blades, each of the four blades being movably mounted on the support structure. The method according to claim 1,
The electric actuator includes a stepper motor. The method according to claim 1,
Wherein the electrical actuator is removably mounted on a bracket attached to the support structure. The method of claim 3,
Further comprising a link assembly connecting the flow controller to the electrical actuator, wherein the link assembly is configured to cause the electrical actuator to rotate the flow controller about the hinge. The method of claim 4,
Further comprising a plurality of link assemblies, each link assembly connecting each blade of the plurality of blades to the electric actuator. The method of claim 8,
A shaft hole and a link hole are formed in the support structure,
The electric motor including a screw shaft extending substantially upward through the shaft hole of the support structure,
The link assembly includes:
A hub screwed into the screw shaft of the electric actuator;
A first link attached to the hub at one end and extending downwardly through the link aperture of the pile structure;
A second link rotatably mounted to the support structure at one end;
A third link rotatably mounted to the flow controller at one end; And
A fourth link,
Wherein one end of the fourth link is rotatably connected to the other end of the first link and the other end of the fourth link is rotatably connected to the other end of the second and third links. The method of claim 10,
Wherein the hub is operatively coupled to the threaded shaft of the electric actuator. The method according to claim 1,
And a mounting hole for mounting and removing the electric actuator is formed in the support structure. The method according to claim 1,
Further comprising a guide attached to the support structure and extending substantially upward to prevent rotation of the flow controller. 14. The method of claim 13,
Wherein the electric actuator includes a screw shaft extending substantially upward,
Wherein the flow controller is provided with a shaft hole and a guide hole, the flow controller is screwed with the screw shaft of the electric actuator through the shaft hole, and is slidably engaged with the guide through the guide hole. The method according to claim 1,
Wherein the flow controller is a disc. The method according to claim 1,
Further comprising an exterior plate removably attached to the support structure. 18. The method of claim 16,
Wherein one edge of the exterior plate is rotatably hinged to a bracket attached to the support structure and the opposite edge of the exterior plate is releasably secured to the support structure. The method according to claim 1,
And an insulating layer disposed on at least a portion of the flow controller. The method according to claim 1,
Further comprising a sensor for measuring the room temperature, the temperature of the supply air, or the flow rate of the supply air. The method according to claim 1,
The diffuser housing comprises:
A diffuser neck configured to be coupled to the feed air conduit; And
And a diffuser cone configured to discharge the supply air at an angle to the downward direction,
Wherein the diffuser neck and the diffuser cone are integrally formed or joined to each other. As variable air diffusers,
A diffuser housing formed to be coupled to the feed air conduit and having an outlet for the discharge of feed air into the chamber from the feed air conduit;
A support structure attached to the diffuser housing;
A plurality of blades movably mounted on the support structure for varying the amount of supply air exiting through the outlet; And
And a link assembly connecting the plurality of blades to the electric actuator,
With the diffuser housing coupled to the supply air conduit and with the support structure attached to the diffuser housing and connected to the link assembly, the electrical actuator is accessible from the chamber and removed from the diffuser housing Variable air flow diffusers. As variable air diffusers,
A diffuser housing formed to be coupled to the feed air conduit and having an outlet for the discharge of feed air into the chamber from the feed air conduit;
A support structure attached to the diffuser housing and defining a mounting hole;
A flow controller for varying the amount of supply air exiting through the outlet;
A guide attached to the support structure and extending substantially upward to prevent rotation of the flow controller; And
An electrical actuator mounted on the support structure through the mounting hole for moving the flow controller to change the amount of supply air,
Wherein the diffuser housing is coupled to the supply air conduit and the support structure is attached to the diffuser housing and the flow controller is held within the diffuser housing, A diffuser (10) in accordance with claim 1, wherein the diffuser (20) is removable from the diffuser housing (20).

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