The invention relates to an electric duct heater that has universal installation capabilities as well as the ability to be used in both standard type duct heating applications and duct heating applications involving equipment such as valves or duct transitions.
Electric duct heaters are well known for use in heating air which can be supplied to rooms or spaces through HVAC ducts. The design of these duct heaters is well known and they have been built for many years. They are also regulated for safety performance through UL Standard UL1996. This UL1996 standard is a very stringent standard for practices and evaluation and relates to the placement of duct heaters at a particular spacing from equipment, structure or the like that is part of or related to the duct containing the electric heater.
Another standard for electric heater applications is UL 1995. This standard controls the electric heater design when it is incorporated into a piece of equipment or other structure that would be near the heater. An example of such a heater would be the heater found in conventional ducted packaged terminal air conditioner (PTAC) units or typical residential HVAC systems. These types of heaters do not necessarily involve the placement of the heater in a duct so that the standards controlling the design for these types of equipment heaters are different than electric duct heaters.
What this means is that not all duct heaters have application as equipment heaters and not all equipment heaters have application for duct heating.
Most present day duct heaters are built with safety limit controls.
An auto limit 101 will open to turn power off at specified temperatures and automatically close when cooled to some lower temperature, allowing the heater to restart if needed. A backup limit 103 can typically be a one-shot device, meaning this device opens at a specified temperature and does not close again, forcing a technician to replace the device to repair the heater. Also, the backup limit 103 can be a manually-resettable device that opens and can be manually reset by pushing a reset button (typically located on the device) to re-establish power and return the heater to operational status, as needed.
Still referring to
The backup limit 103 is typically set at a higher temperature than the auto limit 101 for cut-oft the idea being the auto limit 101 can open and close at a lower temperature range to keep air supply temperatures lower (if needed), and the higher temperature target of the backup limit 103 would function if the temperature continued to rise for some reason, or if the auto limit 101 fails to function properly, etc.
As shown in
In order to maintain the functionality of the duct heater for different installations, differently designed duct heaters must be used. This is shown in
This also becomes a problem if the installer does not realize the direction of air flow in the duct. Specifying a “left hand” duct heater may not work when the installer realizes that the air is flowing in the opposite direction to his/her understanding and this is affecting duct mounting location, access, or special limitations.
Thus, a need has developed to provide improved heater designs that lead away from the requirement of different heaters for different types of installations or installation characteristics. The present invention is directed to solving this problem.
Another problem with duct heaters is that they are not readily adapted or co-adapted for use for applications that would be required to meet UL 1995 standards and without additional testing. The invention is also directed to this problem and produces a heater design that can be used to meet either UL 1996 or 1995 standards.
This inventive heater, in one mode, is designed and constructed such that regardless of orientation for a horizontally or vertically installed heater, the function during normal and abnormal operation would be the same. This is principally due to a centrally located automatic over temperature thermostat and the heater element symmetry in relation to this thermostat, regardless of the thermostats temperature setting or type.
Additionally, the design is such that the back up protection thermostat is wired in series either in the control voltage or line voltage circuit, either vertically or horizontally on the same axis as the automatic thermostat, to replicate the same symmetry and further allow for proper function of backup protection regardless of installed orientation.
This inventive heater design allows horizontally and vertically installed units (that are not otherwise sensitive to installation orientation) to be rotated or flipped 180 degrees without change in function or safe operation. The design also means that the end user can flip or rotate the duct heater by 180 degrees without being concerned about the direction of airflow. The advantage here is that the end installer can flip or rotate the heater to fit the area available on a particular job site and can additionally be confident the airflow direction will not be of concern. So, a single heater is provided for mounting in the side of horizontal or vertical ducts and a single heater is provided for mounting in the top or bottom of horizontal ducts.
Another aspect of the invention is the combination of the unique symmetry design with specific flow control screens having an open percentage in the range of 51% to 67%. These screens or diffusers serve not only to shield surrounding components and materials from radiant energy, but also to evenly distribute air flowing through the heater. This combination results in the ability of an electric heater capable of being used as a stand alone duct heater to be employed as well in an application such as with a single duct variable air volume (VAV) heating system, which may involve a different standard as compared to a stand alone duct heater.
When using the inventive design as part of a single duct VAV heating system, a sizing is performed that relates the restricted inlet and duct size downstream from the inlet so that the duct heater functions in a proper manner. This sizing involves a calculation to determine the downstream duct size limits for a given inlet. Since single duct dampers essentially consist of a shape restriction upstream from the heater, the heater is typically larger than the valve body. The calculation for a range of applicable heater sizes as a function of valve body (shape & size) or restricted inlet is unique to the inventive design and method. This sizing is both applicable for stand alone duct heaters that are positioned with some type of inlet restrictions and single duct heaters with restrictive valve body sizes and shapes that necessarily present a restricted inlet as compared to the duct size of the duct heater.
One embodiment of the invention is shown in
As will be described below, another embodiment of the invention takes the integrated symmetry of the inventive heater design, which is readily usable as a heater for a supply duct under, for example, UL 1996, and further develops a heater for use in an application such as a single duct variable air volume (VAV) damper box, which would be required to satisfy a different standard, likely, UL 1995. Therefore, you have one product that can be used as both a “duct heater” and a “single duct VAV heater”.
Each of
The universal heater assembly 10 and its use in
Again, it should be noted that the diffuser screen is placed on the upstream side of the coils 3. When going from position 1 to position 2, there is no need to move the diffuser screen. However, in position 3, which is a 180 degree flip from position 1, requires the diffuser screen to be moved to the other side of the coil housing 5.
The inventive universal heater for horizontal ducts will work for four (4) mounting configurations, two different orientations for the overhang 2 for each side of the duct. For the vertical duct in
It should be understood that if mercury contactors are used in the heater construction, this will prevent the heater from being flipped upside down in certain installations and therefore the use of mercury contactors provides fewer orientations available for the inventive heater.
The ability of the universal mounting or multi position mounting of the inventive heater duct is related to the configuration of the backup and auto limits. More particularly, one (1) automatic safety limit (auto limit) is provided and it is generally centrally located on a portion of the heater and central with respect to the heating elements. This allows a replication of function and performance regardless of the actual heater mounting orientation, which is described in more detail below.
Additionally, the use of one (1) automatic limit control being centrally located in a portion of the heater provides the advantage that the usage of multiple automatic limits is avoided. Having multiple auto limits is a common practice in the prior art and having these multiple units can effect the actual heater performance when the mounting orientation is varied in the field.
Another feature of the heater is the use of two (2) backup limits, which are symmetrically located with respect to the heater elements and the auto limit. With this configuration, one can utilize these same devices “electrically”, i.e., in many circuit designs to have a very full kw/voltage combination offering over the entire scope of this heater's use and application in the marketplace.
When considering that the heater elements are arranged in a given plane, vertically as shown in
While
As noted above and with respect to a second aspect of the invention, the design with its unique integrated symmetry can be used to create a “hybrid” heater that can be used in association with equipment such as single duct VAV damper boxes. Even in this use, the duct heater assembly maintains its universality wherein the heater assembly can be flipped and rotated 180 degrees allowing it to be used in most mounting positions.
In this mode, the inventive heater is really a dual use heater, whereby the heater has the ability to be used as a conventional or stand alone duct heater for installation into supply air ducting, i.e., without any interfacing or design constraints from nearby equipment or structure, and one that can be mounted in many different positions for horizontal ducts, side or top/bottom mounting, and for vertical ducts and all the vertical duct side mounting capability. Further, the dual use permits the heater to be utilized for applications involving equipment or structure, for example, restricted inlets as explained below.
Another advantage of the invention in its symmetry for the backup limits is that not only can performance be maintained (in many mounted positions), this symmetry allows for a smooth transition “for electrical usage”, between single and three phase electrical systems. Advantages are also gained for the electric heat transition points for load amps and volts as well as system loads from less than 48 amps to system loads greater than 48 amps.
These schematics show a single auto limit that opens the entire heater should deactivation be required.
As shown above, the use of two (2) backup limits allow the system to be symmetrical. Wiring these devices to create a safe circuit allows for the ability to build heaters to accommodate many voltages, phases and amperages. Therefore, this system allows for flippable heaters to be possible and using these devices in the quantities shown and wiring them as exemplified here and according to the skill in the art, allows heater amperages (and thus voltage/phase/and heater kw's) above and below the 48 amp sub-division point.
The second aspect of the invention will now be discussed. As mentioned above, the inventive heater with its universal design is also adapted for use in an application that would go beyond the typical stand alone heater duct installation. This second aspect encompasses applications that would likely be governed by UL 1995, wherein the heater installation has to deal with nearby structure or equipment. An example of such an application is a single duct VAV damper box, wherein a duct having the duct heater therein is linked to a restricted inlet. By restricted, it is meant that the inlet to the duct holding the heater is either the same size as the heater duct or smaller and can be restricted further by function.
As mentioned above, when a heater is closer to a piece of equipment than a specified dimension as regulated by UL standard, e.g., 48 inches in the case of UL 1996, a different standard applies to determine an acceptable arrangement between the heater and surrounding equipment as well as the heater construction itself.
According to the invention, the universal heater described above includes other features and a relationship with the restricted inlet geometry/dimensions that permits it to function properly and to industry standard as a heater in these types of applications.
The inventive and symmetric heater design is especially adapted to be used within a given distance, for example, 20 inches, from a piece of equipment/structure such as an air inlet valve body. This type of a valve body is typically the transition from a round inlet to rectangular outlet made when utilizing a single duct VAV damper box.
Referring back to
The invention in this regard has two features to permit the location of the inventive duct heater in close proximity to equipment such as the valve body 21 in the damper box 19. One feature is the use of a diffuser screen 7, see
Through a progression of testing and designing during Electrical Testing Laboratory (ETL) investigations, a relationship is determined between the restricted inlet, i.e., the size of the restricted inlet, and what size the duct containing the duct heater should be for proper performance when a diffuser screen-containing heater is placed within a certain distance to the equipment in question, e.g., 20 inches from the end of a restricted inlet facing the heater, which may carry a valve for air flow control. The distance must be sufficient so that if a valve such as a baffle or flap valve is present and is fully open, the heater does not contact the edge of the valve and cause a problem in valve operation.
This relationship can be defined when considering the differences between the size of the restricted inlet dimensions and the dimensions of the duct containing the heater.
The following
Referring to
When considering when xmin is zero, this means that the duct cannot be smaller than the size of the inlet. For the y axis, which is the horizontal line through the center of the circle formed by the restricted inlet, the dimensions on the y axis can be no greater than 4 inches. The restriction for the x axis also applies to the y axis, that is, the duct cannot be smaller than the restricted inlet dimension on the y axis.
When considering the calculation shown in
When using the restricted inlet dimensions, the distances between the sides of the duct and edges of the inlet are measured at the point where the edge of the inlet is closest to the face of the duct. For the circular inlet in
What
The inventive heater design is further unique in that it can be used for multiple type and shaped “restricted” inlets and can accommodate differently made and actuated valves. One type of valve is the baffle or flap valve shown in
Turning back to the heater diffuser screen shown in
In the prior art, the typical method of controlling these problems is to vary the heating power produced in order to avoid creating hot spots.
In contrast to this approach for avoiding hot spots, the inventive heater design with the diffuser screen 68, see
The purpose of this diffuser screen is two fold. One purpose is to protect the equipment like the valve from excessive radiant heat from the duct heater itself. The other purpose is to more evenly distribute the air flow over the heater. The diffuser screen is not needed for duct heater application only.
This diffuser screen can take virtually any screen design provided that its opening area is in a range of from 51% to 67%. Going below the 51% open area percentage means that there is an insufficient passageway for air travel and an insufficient amount of air passes to the heater itself. This can result in the problem sought to be alleviated, hot spots, and create safety issues. Allowing too much air to pass over the heater elements, i.e., having a screen with an open area of more than 67%, adversely affects the heater element performance, e.g., radiant heat effects are compromised.
Additionally, these screens (used in the % open range mentioned) are placed over the entire face of the heater and act as the radiant shield, thus protecting the upstream components from excess radiant energy created under low airflow conditions.
Therefore, the new inventive heater does not limit the power produced by the heater for more even performance in adverse conditions, but uses the screens as an “Air Limiting/Metering Device” to even airflow and further provide a shield from the radiant energy, thus helping protect upstream components.
As such, an invention has been disclosed in terms of preferred embodiments thereof which fulfills each and every one of the objects of the present invention as set forth above and provides a new and improved duct heater and method of use.
Of course, various changes, modifications and alterations from the teachings of the present invention may be contemplated by those skilled in the art without departing from the intended spirit and scope thereof. It is intended that the present invention only be limited by the terms of the appended claims.
This application claims priority under 35 USC 119(e) based on provisional application No. 61/754,183, filed on Jan. 18, 2013.
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