Eyelet for Steam Humidification System

Abstract

The steam eyelet(s), mounted on steam dispersion tube(s), part of a steam dispersion system, has an interior cavity fed with steam, a through passage, a steam entry port and a steam exit port. The exit port is partly closed by a sloped throat which captures steam condensate and the steam entry port has a drain slot which drains condensate into the dispersion tube cavity. The eyelet's through passage progressively narrows at the exit with a shallow and then steep slope. A protruding lip reduces facial formation of condensate. A method reduces condensate spitting by accumulating condensate in the interior of the eyelet which, when it reaches a certain volume, drains the condensate bubble-droplet with an inboard interior eyelet surface disruption near the steam entry. Surface tension of the condensate bubble-droplet is used to drain the bubble-droplet at the disruption, causing an out-flow of the bubble-droplet in a direction contrary to steam flow.

Description

The present application is a regular patent application based upon and claiming the benefit of provisional patent application Ser. No. 61/896,377, filed Oct. 28, 2013, now pending and is a continuation-in-part of U.S. patent application Ser. No. 13/746,175, filed Jan. 21, 2013, now pending, the contents of which is incorporated herein by reference thereto. This invention relates to a steam eyelet one steam dispersion tubes in a steam dispersion humidification system and more particularly, since humidification systems typically use multiple dispersion tubes and each tube has multiple steam exit ports, to a plurality of steam eyelets on one or more steam dispersion tubes in a steam dispersion humidification system.

BACKGROUND TO THE INVENTION

Most modern commercial and industrial buildings are equipped with steam humidifiers mounted within the heating and air conditioning systems. Steam from the steam boiler, district steam system or steam generating humidifier is introduced into a ducted air stream and distributed throughout the building. Generally speaking, it is not advisable to allow humidification steam to condense into water in a duct system as such damp areas can become breeding grounds for algae, bacteria and organic contamination.

There have been a variety of steam humidification systems, apparatus and methods that have heretofore been developed in order to control condensate. For example, US Publication US2009/0121367 relates to a steam dispersion apparatus having a steam chamber communicating in an open-loop arrangement with a first steam source for supplying steam to the steam chamber, which steam chamber includes a steam dispersion location at which steam exits therefrom at atmospheric pressure. The heat exchanger communicates in a closed loop arrangement with a second steam source for supplying steam to the heat exchanger at a pressure higher than atmospheric pressure to convert condensate formed by the steamer chamber back to steam when the condensate contacts the heat exchanger.

Another arrangement is illustrated in U.S. Pat. No. 5,516,466 which relates to a steam humidification system comprising a manifold for receiving steam and at least one steam dispersion tube extending from the manifold for receiving steam. U.S. Pat. No. 6,065,740 shows a steam distribution device for a steam humidification system comprising a horizontally mounted steam dispersion element for receiving steam from the source of steam and for dispersing a portion of the steam into an air stream.

Moreover, U.S. Pat. No. 6,227,526 illustrates a steam dispersion device for a steam humidification system which includes a source of steam, a horizontally mounted steam dispersion element for receiving steam from the source of steam and for dispensing a portion of the steam into an air stream, a horizontally mounted jacket partially surrounding the steam dispersion element and unconnected to the source of steam for maintaining the temperature of the steam dispersion element at or about the temperature of the steam.

U.S. Pat. No. 4,913,856 relates to a humidifier system where atomized water is caused to be rapidly evaporated as a result of being strategically located in the path of high velocity turbulent air created by converging deflector vein sets. Yet another arrangement is shown in U.S. Pat. No. 5,543,090 which relates to apparatus for introducing steam into an air stream in an HVAC system which includes a supply header-steamed dispersing structure and structure reflecting condensate from the steam dispersing structure.

Moreover, U.S. Pat. No. 6,065,740 relates to a steam distribution device for a steam humidification system. U.S. Pat. No. 6,227,526 relates to a steam distribution device for a steam humidification system which includes a source of steam, a horizontally mounted source of steam dispersion element for receiving steam from the source of steam and for dispersing a portion of the steam into an airstream.

U.S. Pat. No. 6,488,219 shows a steam humidifier with pressure variable aperture. Also, U.S. Pat. No. 6,631,856 illustrates a humidifier for providing moisture to an airstream which comprises a pipe having a first end for connecting to a source of steam end a closed second end; first and second slots disposed opposite each other and longitudinally along a major portion of the length of the pipe; and a plurality of members sandwiched within the first and second slots, the members being disposed toward the interior of the pipe to guide condensate into the interior of the pipe. Also U.S. Pat. No. 7,980,535 teaches a demand activated steam dispersion system.

Moreover, there are various prior art devices and methods which illustrate a variety of steam distributors or pipe. For example, U.S. Pat. No. 4,265,840 teaches a vapour distributor pipe for an air humidifier.

Furthermore, U.S. Pat. No. 5,126,080 relates to apparatus for introducing steam into an air stream in a heating, ventilating and air conditioning system which includes a supply header, steam distributing structure and structure for collecting condensate from the steam distributing structure. This patent also illustrates a variety of distributor pipes. Also, U.S. Pat. No. 5,372,753 illustrates an apparatus for introducing steam into an air stream in an HVAC humidification system which illustrates distribution pipes disposed in a vertical orientation.

The prior art also discloses a variety of different apparatus and methods for insulating the distribution apparatus in an effort to minimize condensate. For example, U.S. Pat. No. 7,744,068 teaches a distribution system which includes insulation where the insulation covers at least a portion of the steam dispersion tubes, the insulation defining an opening aligned with the opening of the steam dispersion tube where the insulation meets 25-50 flame/smoke indices for UL 273/ASTME-84 and has a thennal conductivity less than about 035 Watts/n-K (2.4 in/hr/st2 deg Fl. The insulation includes polyvinylidene flouride.

Moreover, U.S. Pat. No. 8,092,729 relates to a method of attaching insulation to a steam dispersion tube where the insulation includes polyvinylidine flouride.

These and other prior art systems, apparatus and method relating to humidification dispersion systems present relatively complicated structures. Moreover, the dispersion pipes and insulation methods and systems present relatively complicated structures.

OBJECTS OF THE INVENTION

It is an object of the present invention to provide a steam exit port eyelet which gathers steam condensate, and then when the condensate reaches a certain volume (established by the interior surface configuration of the eyelet), the condensate bubble or droplet is pulled out of the interior of the eyelet by an inboard interior eyelet surface disruption near the steam entry port of the eyelet. The surface tension of the condensate bubble or droplet causes the droplet to be pulled into the disruption surface and the condensate bubble or droplet flows out of the interior of the eyelet in a flow direction contrary to the steam directional flow. The inboard interior eyelet surface disruption being a notch or a slot or other surface inboard channel which causes the steam condensate droplet to (a) grip the surface disruption, and then (b) pull the condensate droplet into the surface disruption.

It is another object of the present invention to have a plurality of eyelets one a singular steam dispersion tube, and when multiple steam dispersion tubes are used, to employ plurality of eyelets on each steam dispersion tube.

It is a further object of the present invention to provide an eyelet with interior surface features and a protruding lip which facilitates the capture of steam condensate at the steam exist port of the eyelet to build up the condensate bubble or droplet. This feature is contrary to most condensate elimination theories because the present system may increase condensate formation at the steam exit port of the eyelet.

It is a further object of the present invention to reduce or eliminate “spitting” of steam condensate from the exist port of the eyelet. The spitting (or forceful ejection of condensate) is caused by condensate accumulation at the steam exit port whereby the force of the steam flow through the steam eyelet causes droplet formation at the edge of the steam exit port further causing the droplet to become airborne and be ejected by the forceful steam flow outboard of the exit port. The interior surface features of the eyelet cause the formation of a large condensate droplet, thereby reducing or eliminating spitting of steam condensate from the exist port of the eyelet because the (a) droplet is too large, heavy or dense to break up and form airborne ejectable droplets or (b) the surface tension of the condensate droplet is too high compared with the forceful steam flow outboard of the exit port.

Another object of the present invention is to reduce the formation of steam condensate on the outboard surface edge(s) of the steam eyelet with a protruding lip near the steam exit port.

The eyelet of the present invention can be used with the steam dispersion systems shown in FIGS. 1-13 herein or with various prior art steam dispersion systems. Prior art steam dispersion systems are listed above in the Background of the Invention section.

Accordingly, it is an object of this invention to provide an improved steam dispersion system, apparatus and method as compared to the prior art.

It is another object of the present invention to provide a steam eyelet which limits the condensate spit out from the steam dispersion tubes.

SUMMARY OF THE INVENTION

The steam eyelet (or a number of eyelets) is mounted on or in a steam dispersion tube as part of a steam dispersion system. The steam dispersion tubes each have an interior cavity which is fed steam from a source of steam. The eyelet has an eyelet body defining a through passage with a steam entry port at one end and a steam exit port at the other end wherein steam passes through the through passage from the interior of the steam dispersion tube and exits through the exit port. The steam exit port is partly closed by a sloped throat in the through passage which captures condensate thereat. Also, the steam entry port having a drain slot in the through port which drains condensate into the dispersion tube cavity.

The cross-sectional area of the eyelet's through passage narrows in the vicinity of the steam exit port. More precisely in an enhanced embodiment, the cross-sectional area of the through passage progressively narrows in the vicinity of the steam exit port with a sloped throat having a shallow slope region and a steep slope region. The steep slope is adjacent the exit port and the shallow slope is more inboard of the exit port, in the eyelet through passage.

In another refinement, the eyelet has a protruding lip on an outboard face of the exit port. The through passage's sloped throat, shallow slope region is near the lip.

The present invention is also a method for reducing steam condensate spitting from eyelets on steam dispersion tubes in a steam dispersion system. The method includes accumulating steam condensate in an interior of the eyelet and, when the condensate reaches a certain volume in the eyelet, the condensate bubble or droplet is pulled into an inboard interior eyelet surface disruption near the steam entry port of the eyelet. The refined method uses the surface tension of the condensate bubble or droplet to draw the droplet via the disruption surface out of the eyelet and causes the condensate bubble or droplet to flow out of the interior of the eyelet in a direction contrary to the steam directional flow.

It is an aspect of this steam humdification system to provide a steam dispersion system comprising steam dispersion apparatus, a source of steam at a pressure higher than atmospheric, a steam header communicating with the source of steam and operable in a closed and open loop for supplying humidification steam to the steam dispersion apparatus configured to provide humidification steam to the air in the open loop, and inhibiting the fonnation of condensate in the steam dispersion system in the closed loop. The steam in the heat exchanger is at a pressure higher than atmosphic, while the pressure in the dispersion apparatus is at atmospheric pressure.

It is another aspect of this steam humdification system to provide steam distribution apparatus comprising a heat exchanger header defining a chamber, a steam distribution apparatus communicating with the heat exchanger chamber, a source of steam at a pressure higher than atmospheric, a heat exchanger having one end communicating with the source of steam at a pressure higher than atmospheric, and another end of the heat exchanger for communicating with the chamber and steam dispersion apparatus at atmospheric pressure; a control valve for operating the heat exchanger header in an open-loop for supplying humidification steam to the steam distribution apparatus at atmospheric pressure; an isolating valve operating in a first preheat stage to preheat the heat exchanger, heat exchanger header.

It is a further aspect of this steam humdification system to provide a method of humidifying air using steam comprising supplying a source of steam at a pressure above atmospheric pressure to a heat exchanger disposed within a header defining a chamber wherein the chamber communicates with steam distribution pipes communicating with the air at atmospheric pressure; isolation valve for supplying the steam to the heat exchanger at a pressure above atmospheric to heat the chamber in a closed-loop, and a controller valve supplying steam to the chamber and distribution pipes to supply humidification steam to the air.

Still another aspect of the steam humdification system relates to a steam dispersion system comprising: steam dispersion apparatus; a source of steam at a pressure higher than atmospheric; a heat exchanger communicating with the source of steam and operable in a closed and open loop; an isolating valve to pre-heat the heat exchanger in a pre-heat closed loop cycle and act as a re-evaporator of condensate in a humidification cycle (when the steam control valve is in the humidification cycle); a steam control valve to operate the steam dispersion system in an open-loop having a pre-heat cycle so as to inhibit condensate formation followed by a control cycle to provide controlled humidification.

Yet another aspect of the steam humdification system relates to a nozzle for steam dispersion tubes, the nozzle comprising a body extending longitudinally about a generally cylindrical axis; a hole through the body whereby the hole has an axis disposed at an acute angle relative to the cylindrical axis to assist in discharging any condensate by gravity.

Another aspect of the steam humdification system provides insulation for a steam dispersion tube having an outer wall with a plurality of aligned nozzles, said insulation disposed about said outer wall where the cross section of said insulation in the vicinity of the nozzles is less than the cross section of the insulation remote from said nozzles.

These and other objects and features of the invention will now be described in relation to the following drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention relates to a steam eyelet in a steam dispersion humidification system and more particularly relates to a plurality of steam eyelets on one or more steam dispersion tubes in a steam dispersion system. FIGS. 1 to 13 describe certain configurations of steam dispersion humidification systems and FIGS. 14 to 18 illustrate the inventive steam eyelet. Please note that the steam eyelet can be used in various different steam dispersion humidification systems, other than those described in connection with FIGS. 1 to 13. See the Background of the Invention section for other steam humidification systems.

FIG. 1 is a schematic view of one embodiment of the steam dispersion system.

FIGS. 2a, 2b, and 2c, are side views, elevational view, and exploded view respectively of the steam dispersion system shown in FIG. 1.

FIGS. 3a and 3b are actuated steam control valve operating sequence charts in a pre-heat stage and a controlled stage respectively.

FIG. 4 is a schematic view of another embodiment of the steam humdification system.

FIGS. 5a, 5b, 5c are elevational, front elevational and exploded views of the embodiment shown in FIG. 4.

FIG. 6 is a perspective view of the embodiment shown in FIGS. 4, 5a, 5b and 5c.

FIG. 7 is another perspective view of FIG. 6.

FIGS. 8a, 8b, 8c are schematic side elevational views, another side elevational view, and a exploded view, respectively, of another embodiment of the steam humdification system where the distribution tubes are in a horizontal orientation.

FIG. 9 is a side elevational view showing insulation on the steam distribution tubes.

FIG. 10 is a front view of a nozzle.

FIG. 11 is a cross sectional view of FIG. 9.

FIG. 12 is a cross sectional view of one nozzle.

FIG. 13 is a top plan view of another embodiment of the steam humdification system showing the insulation.

FIG. 14 is a side elevational view of the steam eyelet.

FIG. 15 is a cross-sectional view of the eyelet from the perspective of section line A′-A″ in FIG. 14.

FIG. 16 is an end view of the eyelet showing the inboard slot, that is, inboard with respect to the interior of the steam dispersion tubes.

FIG. 17 is a front, perspective view of the eyelet.

FIG. 18 schematically illustrates the interior of the eyelet with accumulated condensate.

DETAILED DESCRIPTION OF THE INVENTION

Like parts are given like numbers throughout the drawings and description herein. In the drawings, embodiments of the invention are illustrated by way of example. It is to be expressly understood that the description and drawings are only for the purpose of illustration and as an aid to understanding, and are not intended as a definition of the limits of the invention.

FIGS. 1 and 2A, 2B, 2C illustrate one embodiment of the steam humdification system. In particular, the FIGS. 1 and 2 illustrate a steam distribution system 2 which includes steam dispersion apparatus 4 as generally illustrated in the drawings of the description herein. FIGS. 1 and 2 illustrate the steam distribution tubes 12 in a vertical orientation.

In particular, the steam distribution apparatus 4 includes a steam header 6, a heat exchanger 8 and the piped assembly apparatus as shown in the drawings. The steam header 6 can comprise of a variety of materials including sheet metal, steel, iron, cast iron, copper or the like. The steam header 6 can be made from two or more pieces so as to permit the insertion of the heat exchanger 8 within a steam header chamber 11. The heat exchanger 8 as disclosed in FIG. 1 can be made from a one piece hollow copper tube having a primary steam inlet 32 and a steam outlet 34. The heat exchanger 8 can also be made from stainless steel, copper, sheet metal, iron, cast iron or the like.

The steam distribution apparatus 4 also includes a steam source 50 with a primary steam supply line 9 that communicates with the primary steam inlet 32 that will communicate with the heat exchange chamber 10 so as to heat up the heat exchanger 8 and header 6. Thereafter steam will exit the steam outlet 34 toward a steam separator 26. The steam separator 26 separates the steam 25 into two paths namely S1 and S2. The steam S1 communicates with the steam supply pipe 10 that feeds the steam injector 40 disposed in the header 6 as shown in FIG. 1. The steam injector 40 includes a plurality of exit steam holes 16. In one embodiment, the exit steam holes 16 are disposed so as to face the heat exchanger 8 so that if there is any condensate in the steam S1 exiting the exit steam holes 16, the condensate will drop onto the heat exchanger 8 by force of gravity so as to be re-vapourized as steam.

The steam distribution apparatus to be described herein has been designed so as to minimize the presence of condensate and thereby provide a more efficient steam distribution system 2 and apparatus 4.

In the embodiment shown in FIG. 1, the heat exchanger 8 is made of one large diameter copper tube. The heat exchanger 8 has a larger diameter than the steam carrying supply line 9 so as to carry sufficient energy to evaporate the condensate formed in the steam distribution tubes 12 and to evaporate internal condensate of the heat exchanger 8.

FIGS. 1 and 2A, 2B, 2C illustrates a horizontal application of the steam header 6. The heat exchanger 8 is placed directly under the steam holes 16 of steam injector 40 of the vertical steam distribution tubes 12 in such a manner as to ensure that the condensate from the steam distribution tubes 12 falls on the upper portion of the heat exchanger 8.

The control steam supply pipe 10 (see port 43) coming from the actuated steam control valve 18 will be connected to the steam injector 40 placed above the heat exchanger 8 so that any residual condensate in that pipe will fall on the upper part of the heat exchanger 8.

In particular part of the steam injector 40 can also extend into the steam header 6 and will include exit steam holes 16 pointing downwards toward the heat exchanger 8 in such a manner so as to have any residual condensate after the actuated steam control valve 18 fall on the upper part of the heat exchanger 8.

The heat exchanger 8 has in one embodiment a construction comprised of an inlet primary steam supply pipe 9 which communicates with the isolation valve 20 directly into the heat exchanger 8 by connecting the primary steam inlet 32.

As best illustrated in FIG. 2A, the bottom surface 31 of the header 6 includes angled surfaces 30 to bring the condensate to close proximity of the heat exchanger 8 as well as reduce the surface area of the header 6 in order to reduce energy loss.

Operation Description

The controller 60 can comprise of a variety of devices including computers, micro processors, or the like. In one embodiment, the controller 60 can be wired to the various steam distribution apparatus 4 as described in this application or it can communicate wirelessly with the steam distribution apparatus 4 both in sending and receiving signals therefrom.

In one embodiment of the steam humdification system, the temperature range of the distribution apparatus 4 can be pre-programmed in the controller 60.

The controller 60 reads the temperature at the upstream temperature sensor 22 and compares it to a pre-determined range of operational temperatures. The temperature range can be derived from the system's steam pressure.

The isolating valve 20 can be programmed to fully open only if the temperature at sensor 22 falls within the pre-determined temperature range. The steam from source 50 will then heat up the heat exchanger 8 and the steam separator 26 and the temperature sensor 24 downstream of the heat exchanger 8. When the temperature at the temperature sensor 24 is within a pre-determined selected temperature range, the actuated steam control valve 18 opens at a controlled opening speed and to a pre-determined or selected pre-heat partial opening of the valve 18.

The actuated steam control valve 18 will remain in this position for a pre-determined heating delay, or cycle. Accordingly, the slower opening of the actuated steam control valve 18, the partial opening of the actuated steam control valve 18 and the delay period are forced or controlled by the controller 60 in order to ensure controlled pre-heat of the atmospheric section of the apparatus to be described herein and thus preclude sudden formation of condensate and the resulting ejection of that condensate through the steam distribution tubes 12 into the air ducts.

After the controlled pre-heat cycle of the atmospheric section of the apparatus 4 the actuated steam control valve 18 will then assume its normal control function responding to the actual humidification demand from a humidistat (not shown) by means of the controller 60.

If at any time the temperature read by temperature sensor 24 downstream of the heat exchanger 8 and or at the upstream temperature sensor 22 drops under the selected preset required temperature range, the actuated steam control valve 18 will close at maximum speed, leaving the isolation valve 20 open so as to raise the temperature.

When the humidity demand is satisfied, the actuated steam control valve 18 will close and after a pre-determined delay, the isolating valve 20 will also close. This will allow substantially all the condensate to be re-evaporated by the heat exchanger 8.

Automation

The temperature range of operation is selectively preset in the controller 60 by means of the steam supply pressure in accordance with thermodynamic laws where the steam temperature can be determined by a person skilled in the art.

The low temperature and high temperature of the temperature range may be selectively set in the controller 60 according to these thermodynamic laws; as well as taking into account cumulative errors including errors in sensor readings. For example, the following illustrates one particular setting, although other settings can be selected.

Sensor error has been included above since the sensor in one embodiment can be a brass thermo where the read temperature differs from about 5 degrees celsius from the real temperature value.

Real Temperature Range (Self-Adjusting to any System Supply Pressure)

By using the temperature read at the temperature sensor upstream of the isolating valve 20, the steady state temperature can in one embodiment be determined and recorded in the controller. In this case, the temperature must remain constant with +/−0.5 degrees centigrade for 20 seconds in one of the embodiments of the steam humdification system. The recorded temperature will then be the steam temperature (from thermodynamic laws)—sensor error.

The sequence described above automates the humidifier temperature range operation for any steam supply. The humidifier will properly work even if the steam pressure is unknown by the user and the manufacturer. In other words, the system described herein is self-adjusting to the temperature range.

Actuated Steam Control Valve Opening Sequence

FIG. 3a illustrates one embodiment of an actuated steam control valve opening sequence. In particular FIG. 3a illustrates a pre-heating stage having two time frames, namely the first preheating time frame from 100 to 102 and a second pre-heating time frame from 102 to 104.

The actuated steam control valve 18 opens at a pre-set opening speed POS until the pre-heating valve position PVP has been reached. This represents the first pre-heating time frame 100 to 102 and the slope 99 in FIG. 3a represents the pre-set opening speed POS. The steeper the slope 99 the faster the speed. Once in the pre-heating valve position PVP, steam control valve 18 remains in that position for a certain predetermined period of time namely the heating time delay HTD represented by the second time frame 102 to 104. After the maximum heating time delay HTD marked by 104 in FIG. 3a, the actuated control valve 18 will move at a constant opening speed or faster closing speed to a position determined by a proportional signal coming from the controller 60.

The pre-heating stage 100 to 104 inhibits the fonnation of condensate “spitting” within the system.

FIG. 3b is a representation of the controlled humidification stage which occurs after the preheat stage 104.

After the pre-heat stages 100 and 104 the controller 60 switches from pre-heat operation to control operation based on the humidification demand from the humidistat sensor and sends the proportional demand signal to the control actuated valve 18. The actual humidity in the duct work or in the space to be humidified is read by the humidistat sensor, that communicates with the controller 60. If the humidification demand is lower than the humidity reading by the humidistat sensor, the actuated control valve 18 will close to the proportional position as might be represented by the line 104 to 105. The slope 107 represents the speed of closure of the valve 18.

In one embodiment of the steam humdification system normal control speed has a faster closing than opening speed.

If the humidity demand is higher than the humidistat reading the controller 60 will further open the control valve 18 to the proportional position as might be represented by the line 104 to 103. The valve 18 will open at a pre-determined speed as represented by the slope of line 104 to 103. Line 103 to 105 represents closing of the steam control valve 18; and as previously stated occurs at a faster speed than opening. Thus the slope 109 is steeper.

It is possible that the humidity demand is the same as the humidistat reading in which event the steam control valve 18 will remain in its last position.

Humidifier Automated Operation

Once there is steam demand the following steps are implemented: Step 1. The controller 60 verifies that if the temperature of the upstream temperature sensor 22 upstream of the isolating valve 20 is at the proper pre-selected level. The temperature range as described above depends on the system steam pressure. The system pressure will determine which temperature the steam will be supplied. Step 2. Upon receiving a signal trom controller 60 for humidification demand, isolating valve 20 will fully open only if the measured temperature at the temperature sensor upstream 22 of the isolating valve 20 which is read by the controller 60 is sufficiently high and is within the predetermined range. Step 3. Upon receiving a signal from controller 60 for humidification demand, isolating valve 20 will open and the steam from the steam source 50 will heat up the heat exchanger 8, the steam separator 26 and the temperature sensor 24. When the temperature at the downstream temperature sensor 24 is within the temperature range selected; the actuated steam control valve 18 will start the pre-heat cycle by opening to pre-determined pre-heat position at the preset opening speed. It will stay in the pre-heat position for pre-heat delay time. Step 4. The actuated steam control valve 18 will remain in pre-heating valve position for the predetermined heating delay which is typically between 20-30 seconds as an example of one embodiment. This will allow the steam distribution system 2 to heat up without ejecting condensate through nozzles 75 so as to minimize condensate spitting. Step 5. Then the actuated steam control valve 18 will assume normal proportional control function. Step 6. At any time, any of the temperature sensors 22 or 24 drop under the preset required temperature range, the actuated steam control valve 18 will close at maximum speed, leaving the isolating valve 20 fully open. Step 7. When there is no more call for humidity, the steam control valve 18 will close and after a preset delay, typically 30 seconds as an example, the isolating valve 20 will also close. This will allow all the condensate to be re-evaporated by the heat exchanger.

The controller 60 communicates with inputs from upstream temperature sensor 22, downstream sensor 24, and humidistat. Controller 60 controls or sends an output to steam control valve 18 and isolating valve 20. Communication between controller 60 and the various devices is either by direct wire connection (not shown) or by wireless means in a manner known to persons skilled in the art.

It will be appreciated by a person skilled in the art the vertically orientated distribution tubes 12 are disposed within a duct of an HVAC system. Accordingly, the distribution tubes will be disposed in a generally atmospheric pressure duct system. The steam from the source 50 is typically at a 3-15 psi pressure at 105-121 degrees centigrade respectively. However, the system can operate above 15 psi and the temperature of the steam can also be at other operating temperatures if operated with the steam humdification system as described.

Accordingly, the system 2 as described herein warms up the steam distribution apparatus 4 so as to substantially eliminate the condensate. Generally speaking the condensate if injected into the duct work within a HVAC system promotes the breeding of bacteria and viruses or the like which is an undesirable condition.

Furthermore, the actuated steam control valve 18 is moved (ie opened) to the pre-heating valve position PVP so as to wann up the distribution pipes 12 prior to nonnal modulating or control operation of the humidifier output. At nonnal control operation the output is proportional to the signal sent to control valve 18 from controller 60.

FIGS. 1 and 2A, 2B, 2C also illustrate a steam trap with a vacuum breaker 28.

Furthermore, another embodiment of a horizontally disposed steam header 6 is illustrated in FIGS. 4 and 5a, 5b, and 5c.

FIGS. 4, 5a, and 5b generally include the same steam distribution apparatus as described in FIGS. 1 and 2A and operate in the same fashion except that the steam header 6 and heat exchanger 8 are constructed in a slightly different fashion.

The steam header 6 includes a portion of the primary steam supply line 9 inside the steam header 6 which loops around to communicate with an internal end 3 of the heat exchanger 8. This heat exchanger 8 also includes an exterior steam outlet 34.

Furthermore, the header 6 also includes angled surfaces 30 as previously described so as to force any condensate in closer proximity to the heat exchanger 8 by gravity.

Furthermore, the top ends of the vertical steam distribution tubes 12 include a V-shaped channel 13 so as to fasten the ends of the vertical distribution tubes 12 by means of fasteners 15 and rigidify the apparatus.

Furthermore, FIG. 5c includes an exploded view of the exit steam ejector or steam nozzles 75 which are hollow and disposed within the interior of the vertical steam distribution tubes 12.

FIG. 6 is a perspective view of the embodiment shown in FIGS. 4 and 5A, 5B and include flanges 70a having a plurality of holes 72 adapted to be fastened to a duct system (not shown). Furthermore, the steam header 6 can be comprised of two parts 6a and 6b (see FIG. 5A) so as to accommodate the insertion of the heat exchanger 8 along separation lines 7.

FIG. 7 shows another perspective view of the second embodiment disclosed in the FIGS. 4 and 5.

The operation of the embodiment shown in FIGS. 4, 5, 6, and 7 is similar to that illustrated to FIGS. 1 and 2.

The steam distribution apparatus as illustrated in FIGS. 1-7 generally illustrate the distribution tubes 12 in a vertical orientation. In other words, the distribution tubes 12 are generally disposed perpendicular to the steam header 6. The steam header illustrated in FIGS. 1-7 can also in certain applications be disposed in a perpendicular fashion whereby the steam distribution tubes 12 would be substantially parallel.

FIGS. 8a, 8b, and 8c illustrate another embodiment of the steam humdification system whereby the steam header 6 is disposed in a vertical position and the horizontal steam distribution tubes 19 are disposed in a generally horizontal disposition relative to the steam header 6. More particularly, the horizontal steam distribution tubes 19 are disposed at an acute angle a such that any condensate within the tube 19 will flow downwardly toward the frustoconical collectors 23 as best illustrated in FIG. 8c.

The frustoconical collectors 23 are fastened to the outside surface of the heat exchanger 8 by press fit, soldering, welding, fasteners or the like. The heat from the outside of the heat exchanger 6 will re-vapourize any condensate 29. A plurality of frustoconical collectors 23 are disposed along the outside surface of the heat exchanger 8 as illustrated in FIGS. 8a, 8b, and 8c. Furthermore the upper surface of the frustoconical collectors can include holes to permit the buildup of any condensate to fall to the next lower collector 23.

Furthermore, FIG. 9 illustrates a steam distribution tube 12 which has insulation 90 so as to further discourage the formation of condensate.

Moreover, FIGS. 10 and 11 also illustrate that the nozzle 75 comprises a generally cylindrical body 73 presenting a cylindrical body axis. The body 73 having a hole 77 therethrough. The hole 77 has a hole axis 71 disposed at an acute angle b (FIG. 12) relative to the body axis 71a whereby any condensate within the hole 77 of the nozzle 75 will flow downwardly toward the heat exchanger 8 as illustrated in FIG. 1.

Furthermore, FIG. 11 is a plan view of FIG. 9.

Moreover, FIG. 13 illustrates a top plan view of a vertically disposed steam distribution tube 12 having insulation 90 which has been engineered to minimize formation of any condensate. In particular, the insulation 90 is thinnest in the vicinity of the nozzles 75 and thickest in the region furthest away from the nozzles 75. In one particular embodiment shown in FIG. 13, the insulation is oblong and cross-sectioned. In particular, the insulation 90 has an oblong outside diameter and a circular inside diameter.

The steam humdification system described herein has a number of advantages: (1) The insulation is thicker in the front and back where most of the heat loss occurs. (2) Furthermore, the shape of the insulation has better aerodynamic features so as to lower the static pressure loss. Every interference with the pressure of the steam drops the pressure and airflow and therefore requires more horsepower to compensate for this loss. (3) The nozzle 75 could be made of silicone rubber and is configured to bring the condensate at the cold startup back to the distributor. The inside slope 77a improves such feature. Furthermore, the insulation 90 slips onto the stainless steel tubes forming distribution tubes 12 and 19 so as to perform insulating characteristics on the steam distributor. Furthermore, the shape of the insulation is designed to increase the efficiency without reducing the effective airflow section. The shape also reduced the pressure drop acting like a diverter instead of a baffle. More particularly, on the sides the thickness of the insulation 90 is reduced to avoid blocking the airflow section and also to reduce the nozzle thickness, thereby reducing condensate buildup and cold startup, thus again minimizing spitting of condensate.

The material used for the insulation is silicone foam rated UL723 and also UL94 VI. The foam reduces at maximum the heat transfer increasing the efficiency of the humidifier. The steam distribution system 2 and steam distribution apparatus 4 described herein includes the following advantages: (1.) A closed/open loop system where the heat exchanger is in a closed system and the steam injector is in an open system. (2.) The heat exchanger has a diameter substantially larger than the steam carrying parts. (3.) Any condensate from the steam distribution pipes 12 and 19 fall directly onto the heat exchanger 8. (4.) Steam injector 40 is forced to send steam and condensate directly onto the heat exchanger 8. (5.) The angled bottom 30 of the steam header 6 force condensate into close proximity of the heat exchanger 6. (6.) The arrangement in the horizontal application of the steam header 6 having frustoconical collectors or cups to collect the condensate on the heat exchanger. (7.) There is no drain of condensate needed since all condensate is moved back into the boiler (not shown), or re-evaporated. (8.) The controller 60 ensures an automatic startup. (9.) The actuated steam control valve 18 is operated at two distinct speeds determined by the controller 60; namely, startup speed (very slow in order not to create spitting of condensate from the steam distribution tubes) and operational modulating speed for operation mode. (10.) There is an automatic response to sudden pressure drop and energy conservation in the off mode.

With respect to the steam eyelet invention, similar numerals designate similar items in FIGS. 14-18. This group of Figures are discussed concurrently herein wherein FIG. 14 is a side elevational view of the steam eyelet 80; FIG. 15 is a cross-sectional view of eyelet 80 from the perspective of section line A′-A″ in FIG. 14; FIG. 16 is an end view of eyelet 80 showing the inboard slot 88 (an inboard interior eyelet surface disruption), that is, inboard with respect to the interior of the steam dispersion tubes (tubes not shown, but see FIG. 13); FIG. 17 is a front, perspective view of the eyelet 80 showing the steam exit port 84; FIG. 18 schematically illustrates the interior 86 of eyelet 80 with multiple levels of accumulated condensate 94.

FIG. 12 shows an eyelet 75 with an interior 77 with a downward slope 77a. The eyelet 75 is attached to a steam distribution pipe 12 in FIG. 13. The inboard end 76a of the eyelet 75 is open to the interior 12A of the steam distribution pipe 12. The outboard end 76b of eyelet 75 permits the steam to exit the steam distribution pipe 12. In general, the eyelet 75 is cylindrical but other shapes are possible. The interior 77 of the eyelet 75 has shapes or configurations that reduce or eliminate spitting of condensate. In FIG. 12, the interior 77 of the eyelet 75 has a sloped shape 77a wherein the size of the outboard eyelet opening 76b is smaller than the largest interior diametric size of the eyelet (the largest being inboard steam entry port 76a), and the slope 77a forms a declination from the outboard edge 76b to the other interior space near inboard edge 76a of the eyelet 75. FIG. 12 shows a single slope 77a (a constant declination from the outboard portion 76b to the inboard portion 76a of the eyelet interior 77).

The improved eyelet 80 (FIGS. 14-18) has (i) a two slope configuration (a steep interior slope 87 near the outboard end 84 of the interior 86 of eyelet 80 and a lesser sloped region 83 more inboard in the interior 86 of the eyelet 80); (ii) a slot or notch 88 near the inboard end 82 of the eyelet 80; (iii) an outboard end surface 92 that is convex (see FIG. 14) and protruding with respect to the vertical face 84 of the outboard edge of the remainder of eyelet 80.

The eyelet 80 in FIGS. 14-18, has an internal slope 83, 87 to bring condensate down to the steam entry port 82 at the inboard passageway or cavity 12A of steam dispersion tube 12 (see FIG. 13). The eyelet 80 has an internal throat near exit port 84 to prevent ejection or spitting of condensate accumulating at the exit port face 84.

The level or amount of condensate generated inside eyelet 80 increases (see FIG. 18) and remains in the interior 86 of the eyelet 80 because of water surface tension. The accumulation 94 is contained in the throat region (surface 87, 85) until the accumulation 94 reaches the notch or surface disruption 88 at the back 82 of the internal through passage 86 of the eyelet 80. When the condensate accumulation 94 reaches the slot, notch, surface disruption or drain channel 88, the surface tension will grips in the slot 88 and pulls the condensate 94 back to the inside 12A of the steam dispersion tube 12 (FIG. 13). Tests show the phenomenon of (a) condensate accumulation at the throat 87, 85 and gripping and pulling towards the channel 88. The combination of the slope, throat and slot prevents, reduces or eliminates condensate ejection or spitting from the steam tube 12. In one embodiment, the eyelet 75, 80 is made of silicone with a low thermal conductivity. The silicone eyelet has a high maximum operating temperature (450 F).

The outside round shape 92 of the eyelet 80 prevents steam to get in contact with any eyelet outside round surface 101a, 101b (FIG. 17) preventing condensate generation on the outside surface. In tests, the size of the internal shape 86 allows at least 1 lbs/hr of steam capacity without any condensate ejection.

Eyelet 80 has an entry port 82 which is on the inboard side face of the eyelet generally opened to interior cavity or passage way 12A of steam dispersion tube 12 (see FIG. 13). A through passage 86 permits steam in the direction E to exit eyelet 80 at exit port 84. The interior space 86 of eyelet 80 narrows due to sloped interior surface region 83, 87 which form the throat of eyelet 80 or, more precisely, the throat of through passage 86. The through passage 86 progressively narrows from inboard entry port 82 to exit port 84 because one interior surface 81 is generally plainer, at least with respect to cross sectional plane A′-A″ as further compared with sloped surfaces 83, 87. The degree of slope for service 83 is shallow compared with axial centerline B′-B″ and as further compared with the more severe slope 87. Steep slope 87 is adjacent exit port 84. Shallow slope 83 is defined in an interior region of through passage 86 and, in general, is more inboard with respect to exit port 84. As used herein, the term “inboard” refers to items closer to internal cavity or passage way 12A of steam dispersion 212 (FIG. 13) as compared with other items further away from interior tube space 12A. The throat in interior 86 progressively narrows in the vacinity of steam exit port 84.

The steam entry port 82 has a drain slot 88 in through passage 86 which permits drainage passage of condensation into steam dispersion tube cavity 12A. Drain slot 88 may be a channel, notch, or surface disruption that extends, at one end, into an interior region of through passage 86 and, at the other end, leads to entry port 82. FIG. 16 shows one configuration of this drain slot or channel. In FIG. 15, drain slot or channel has edge 91 on one side and edge 89 on the other side, both of which form channel drain slot 88.

The outer face of exit port 84 has a protruding lip 92 which is convex. The protruding lip extends a distance 93 which is the distance between face line C and face line D. Convex forward or round end 92 is grammatically shown in FIG. 15 and in FIG. 17. In general, entry port 82 is about double the cross sectional area of exit port 84.

The protruding lip 82 reduces the accumulation of steam condensate on faces 101a and 101b in FIG. 17.

The method for reducing steam condensate spitting from the eyelets includes accumulating steam condensate 94 in an interior 86 of the eyelet 80. When the condensate 94 reaches a certain volume in the through passage 86 of eyelet 80, a surface disruption draws the droplet closer to the eyelet's steam entry port. This interior, inboard eyelet surface disruption may be a notch or slot or channel 88. The pulling of the droplet at the surface disruption occurs at the steam entry port 82 of eyelet 80. The surface tension of the condensate double or droplet 94 causes the condensate bubble to flow out of the interior 86 of eyelet 80 in a direction contrary to steam directional flow E. The pulling and draining is caused by drain channel 88. The channel also grips the condensate bubble at the surface disruption and pulls the condensate bubble into the surface disruption. The reduction of steam condensate formation on the upward surface of the steam eyelet is accomplished by accumulating the condensate on protruding lip 92 of the eyelet.

The inventive method provides a steam exit port eyelet which gathers or accumulates steam condensate, and then when the condensate reaches a certain volume (established by the interior volume and surface configuration of the eyelet), the condensate bubble or droplet is pulled to the steam entry port by an inboard interior eyelet surface disruption near the steam entry port of the eyelet. The surface tension of the condensate bubble or droplet causes the droplet to move into the drain slot and thereafter causes condensate flow out of the interior of the eyelet in a flow direction contrary to the steam directional flow. The inboard interior eyelet surface disruption being a notch or a slot or other inboard surface channel which causes the steam condensate droplet to (a) grip the surface disruption, and then (b) pull the condensate droplet into the surface disruption.

The eyelet has interior surface features 86, 85, 87, and a protruding lip 92 which facilitates the capture of steam condensate at the steam exit port 84, 87, 85 to build up the condensate bubble or droplet. See FIG. 18. A large droplet is created relative to the interior volume and size of the eyelet. This feature is contrary to most condensate elimination theories because the present system may increase condensate formation at the steam exit port of the eyelet.

The present invention reduces or eliminates “spitting” of steam condensate from the exit port of the eyelet. The spitting (or forceful ejection of condensate) is caused by condensate accumulation at the steam exit port whereby the force of the steam flow through the steam eyelet in direction E causes droplet formation at the edge of the steam exit port further causing the droplet (or portions thereof) to become airborne and be ejected by the forceful steam flow outboard of the exit port. The interior surface features 83, 85, 87 of the eyelet 80 cause the formation of a large condensate droplet 94, thereby reducing or eliminating spitting of steam condensate from the exit port of the eyelet because the (a) droplet 94 is too large, heavy or dense to break up and form airborne ejectable droplets or (b) the surface tension of the condensate droplet is too high compared with the forceful steam flow in direction E outboard of the exit port 84.

To reduce the formation of steam condensate on the outboard surface surfaces and edges 101a and 101b (FIG. 17) of the steam eyelet 80 (the faces 101a, 101b, being the outboard part of lip 92 and exit port 84), a protruding lip 92 extends outboard away from the outboard port face of the steam exit port.

The claims appended hereto are meant to cover modifications and changes within the scope and spirit of the present invention. Importantly, the eyelet described in FIGS. 14-18 (and nominally in FIG. 12) can be deployed and employed in a variety of steam dispersion systems, in addition to the systems shown in FIGS. 1-11.

Claims

1. A steam eyelet mounted in a steam dispersion tube as part of a steam dispersion system, the steam dispersion tube having an interior cavity which is fed steam from a source of steam through the steam dispersion tube, the eyelet comprising:

an eyelet body defining a through passage with a steam entry port at one end and a steam exit port at the other end wherein steam passes through the through passage from the interior of the steam dispersion tube and exits through the exit port;

the steam exit port being partly closed by a sloped throat in the through passage which captures condensate thereat;

the steam entry port having a drain slot in the through passage which drains condensate into the dispersion tube cavity.

2. A steam eyelet as claimed in claim 1 wherein the cross-sectional area of the through passage narrows in the vicinity of the steam exit port.

3. A steam eyelet as claimed in claim 2 wherein the cross-sectional area of the through passage progressively narrows in the vicinity of the steam exit port.

4. A steam eyelet as claimed in claim 3 wherein the sloped throat has a shallow slope region and a steep slope region, the steep slope being adjacent the exit port and the shallow slope being inboard of the exit port.

5. A steam eyelet as claimed in claim 1 wherein an outboard face of the exit port has a protruding lip.

6. A steam eyelet as claimed in claim 1 wherein an outboard face of the exit port has a protruding lip and wherein the through passage's sloped throat has a shallow slope region and a steep slope region, the steep slope being adjacent the protruding lip of the exit port, the shallow slope of the through passage being inboard of the exit port.

7. A steam eyelet as claimed in claim 1 wherein the entry port opening is double the area of the exit port opening.

8. In a steam dispersion system having one or more steam dispersion tubes with interior passages coupled to a source of steam, one or more steam eyelets on the steam dispersion tubes providing steam through passages which are open inboard to the tube's interior passage, the eyelet comprising:

an eyelet body having an interior cavity;

one end of the interior cavity having a partly closed steam exit port which exist port is outboard said steam dispersion tube;

the other end of the interior cavity having a steam entry port which entry port opens inboard to the tube's interior passage;

a sloped throat adjacent the partly closed exit port adapted to capture condensate thereat; and,

a drain slot adjacent the exit port adapted to drain condensate from the interior cavity and into the tube's interior passage.

9. A steam eyelet as claimed in claim 8 wherein the partly closed steam exit port has a protruding lip which protrudes outboard of said steam dispersion tube.

10. A steam eyelet as claimed in claim 8 wherein the eyelet is elongated with an imaginary axial centerline, wherein the sloped throat has a first and a second sloped surface, the first sloped surface being adjacent to the exit port and having an angular pitch greater than the second sloped surface angular pitch with respect to the axial centerline.

11. A steam eyelet as claimed in claim 8 wherein the sloped throat has different sloped surfaces threat, leading to the exit port.

12. A steam eyelet as claimed in claim 8 wherein the exit port is substantially one half the area of the entry port.

13. A steam dispersion system adapted to the supplied with steam from a source of steam comprising:

one or more steam dispersion tubes with interior passages coupled to the source of steam;

one or more steam eyelets on the steam dispersion tubes providing steam through passages which are open inboard to the tube's interior passage;

said one or more steam eyelets having an eyelet body with an interior cavity;

one end of the interior cavity having a partly closed steam exit port which exist port is outboard said steam dispersion tube;

the other end of the interior cavity having a steam entry port which entry port opens inboard to the tube's interior passage;

a sloped throat adjacent the partly closed exit port adapted to capture condensate thereat; and,

a drain slot adjacent the exit port adapted to drain condensate from the interior cavity and into the tube's interior passage.

14. A steam eyelet as claimed in claim 13 wherein the partly closed steam exit port has a protruding lip which protrudes outboard of said steam dispersion tube.

15. A steam eyelet as claimed in claim 13 wherein the eyelet is elongated with an imaginary axial centerline, wherein the sloped throat has a first and a second sloped surface, the first sloped surface being adjacent to the exit port and having an angular pitch greater than the second sloped surface angular pitch with respect to the axial centerline.

16. A steam eyelet as claimed in claim 13 wherein the sloped throat has different sloped surfaces threat, leading to the exit port.

17. A method for reducing steam condensate spitting from eyelets on steam dispersion tubes in a steam dispersion system comprising:

accumulating steam condensate in an interior of the eyelet; and

when the condensate reaches a certain volume in the eyelet, pulling the condensate bubble or droplet towards the steam entry port with an inboard interior eyelet surface disruption near the steam entry port of the eyelet.

18. The method of reducing steam condensate spitting from eyelets as claimed in claim 17 including draining the condensate bubble or droplet via the surface disruption and causing the condensate bubble or droplet to flow out of the interior of the eyelet in a direction contrary to the steam directional flow.

19. The method of reducing steam condensate spitting from eyelets as claimed in claim 18 including either one or the other or both (a) gripping the condensate bubble or droplet with the surface disruption, and (b) pulling the condensate bubble or droplet into the surface disruption.

20. The method of reducing steam condensate spitting from eyelets as claimed in claim 17 including reducing steam condensate formation on an outboard surface of the steam eyelet by accumulating the condensate on a protruding lip of the eyelet.