US3596263A

US3596263A - Icing condition detecting apparatus

Info

Publication number: US3596263A
Application number: US761556A
Authority: US
Inventors: Michael F Ciemochowski
Original assignee: Holley Carburetor Co
Current assignee: Holley Performance Products Inc
Priority date: 1968-09-23
Filing date: 1968-09-23
Publication date: 1971-07-27
Anticipated expiration: 1988-07-27

Abstract

An icing condition detecting apparatus, by means of transducers, compares the temperature of a monitored surface against the temperature of an established reference temperature and further compares dew point against the temperature of said monitored surface in order to determine if such psychrometric parameters indicate the existence of conditions conducive to frost or ice formation on said monitored surface.

Description

United States Patent [72] Inventor Michell. Ciemochov/ski 3,164,820 1/1965 Hulett 340/234 Warren, Mich. 3,287,974 1 H1966 Ciemochowski 340/234 [21 I Appl No 761,556 3,284,003 11/1966 Ciemochowski 73/17 [22] Flled 1968 Primary Examiner-Robert L. Griffin [451 Patented July 27,1971 E B L 73] Assign "out! cubwur 9 Assistant xammerarry ei 0W1 Attorney-Walter Potoroka, Sr.

Warren, Mich.

[54] ICING CONDITION DETECTING APPARATUS 8 Claims, 2 Drawing Figs.

[52] US. Cl 340/234 ABSTRACT: An icing condition detecting apparatus by 1 "E CI "Gosh 21/00 means of transducers, compares the temperature of a moni- [50] Field of Search 340/234; med surface against the temperamre f an established 324/61; 73/17 53 reference temperature and further compares dew point against the temperature of said monitored surface in order to [56] R'hnnm cited determine if such psychrometric parameters indicate the ex- UNITED STATES PATENTS istence of conditions conducive to frost or ice formation on 3,428,890 2/ 1969 Peck et a1. 340/234 said monitored surface.

Problems of frost formation and icing conditions with respect to stationary turbine engine power plants have not been successfully overcome by devices or apparatus proposed or suggested by the prior art.

It has been found that the air intake of such engines often experiences the formation of frost or ice thereon. Such a formation becomes dangerous, even if the physical size thereof is relatively small, because when such formations break 011' they have been known to puncture, and fracture'iiot only turbine blades but also combustor sections of the engine.

The prior art has attempted to solve this frost and icing problem by the application of heat thereto as by the recirculation of exhaust gases to the engine intake. Such an approach is generally acceptable; however, the manner and means by which the prior art devices attempted to achieve such a solution have not been acceptable.

For example, one prior art device employs a two-conductor grid with an associated heater. However, such a grid will detect the presence of only free water and it is not necessary to have free water to obtain frost formation. That is, any time the monitored surface temperature is 32 F. or below and is equal to dew point, frost will start to form on the surface even in the absence of free water. Accordingly, such prior art devices often failed to either detect the, frost fonnation orprotect the engine because the engine intake surface would often be cooled to temperatures of freezing, or below, by the venturi effect of the air flowing therethrough, and the intake surface reaching dew point would start to have frost buildup even though there was no presence of free water;

Other prior art devices attempted to correct these problems by having the device activated whenever, for example, the ambient temperature was 46F. or below and relative humidity was 90 percent or above. This arrangement is'based on the assumption that a constant temperature gradient would always exist between the engine intake surface temperature and ambient temperature; such an assumption is not true.

Such prior art systems often unnecessarily caused the recirculation of exhaust gases to the engine intake. The supply of such recirculating air or gas causes additional vibrations and stresses to occur in the engine guide vanes andtlierefore the too frequent and unnecessary supply of such gases leads to a shortened engine life because of such attendant unnecessary stresses. Further, the supply of such recirculated heated exhaust gases reduces engine efficiency thereby requiring more fuel for the same output horsepower. Accordingly, it can be seen that such prior art devices were not totallyacceptable because of the often unnecessary resulting reduced engine efficiency and attendant deleterious effects on engine components. T

SUMMARY OF THEINVENTION An icing condition detecting apparatus according to the invention comprises first means for creating a firstt output signal indicating that the temperature of a monitored surface has attained a value equivalent to a predetermined temperature value, second means for creating asecond output signal indicating that the said temperature of said surface is equivalent to dew point, and third means responsive to said first and second output signals for causing actuation of related output means. 4 7

Accordingly, a general object of this invention is to provide an icing condition detecting device which is effective for determining the precise moment at which conditions are proper for the fonnation of frost or ice.

Another more specific object of this invention is to provide an extremely accurate apparatus for detecting icing conditions by analog comparison of psychrorn etric parameters and exact digital switching when certain of such parameters exist.

Another object of this invention is to provide an apparatus as set forth in the preceding objects which will not only detect icing conditions but also cause actuation of associated control and/or warning means for either or both giving warning of the occurrence of such icing conditions and taking appropriate corrective measures as by actuation of heating means associated with a monitored surface.

Other more specific objects and advantages of the invention will become apparent when reference is made to the following detailed description considered in conjunction with the accompanying drawings.

DESCRIPTION OF THE DRAWINGS In the drawings:

FIG. 1 is a schematic illustration of apparatus embodying the invention being employed in combination with a stationary turbine engine power plant provided with an exhaust gas recirculating system; and

FIG. 2 is a schematic illustration of apparatus embodying the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT Referring now in greater detail to the drawings, FIG. 1 illustrates, by way of example, a gas turbine engine 10 having an air intake 12 and exhaust outlet 14. Outlet f4 may be in communication with suitable conduitry 16 having an outlet 18 formed therein communicating with the atmosphere. A valve structure or member 20, situated within outlet orifice 18, is normally in an opened position as shown.

An air intake plenum 22, communicating between the atmosphere and air intake 12, is in communication with conduit means 24 communicating generally between plenum conduit 22 and exhaust conduitry 16. A second normally closed valve 26 situated within interconnecting conduit 24 normally prevents the flow of relatively hot exhaust gases to plenum conduit 22.

Various parameter and reference signal producing means are provided which, as will become apparent, cooperate to exercise certain ultimate control functions. For example, a surface temperature sensing transducer 25 is situated in the throat 28 of intake 12 so as to sense the temperature of the throat surface; further, a surface temperature reference device 30, an ambient temperature sensing transducer 32, and a humidity transducer 34 are each provided so as to direct their respective signals to associated circuitry, schematically represented at 36, from which suitable correlated signals are produced and applied to associated actuator means 38 which may in turn energize a related control 40 as well as other means such as sensory or other signal producing means 42. When conditions dictate, control 40 would cause valve 20 to be rotated to a more nearly closed position while valve 26 would be rotated to a more nearly opened position thereby permitting hot exhaust gases to be admitted to the intake 12 in order to heat the throat surface 28 and any frost or icing situated thereon.

- Referring now to FIG. 2, it can be seen that a source of electrical power 44, preferably regulated, provides electrical energy to surface temperature reference device 30, surface temperature transducer 25, ambient temperature transducer 32 and humidity transducer 34 via conductor 46 (and series situated switch 48) and

respective branch conductors

50, 52, 54 and 56.

Before progressing with the description it should be noted that it is not essential to have the presence of free water in order to have frost or icing formation. That is, any time the surface temperature equals dew point (dew point being defined as that temperature at which a sample of air will have a relative humidity of percent) and is at a temperature of 32 F. or below, frost or icing can form on that surface without the presence of free water in the atmosphere or on the surface.

Accordingly, the surface temperature reference device 30, which may be an adjustable potentiometer, is adjusted and set so as to create an output voltage signal, T on conductor means 58, so as to apply such signal to an electrical comparator 60. The potentiometer 30 may be adjusted so as to have voltage signal T of a magnitude indicative of a temperature of 32 F.

Surface temperature transducer 25, which may be a thermistor, is situated as to be continually reflective of the temperature of surface 28. Accordingly, thermistor 25 continually creates a variable output voltage signal, T on conductor means 62 and

parallel branch conductors

64 and 66, so as to apply such signal to electrical comparator or differential amplifier 60 as well as a second electrical comparator 68.

Ambient temperature transducer 32, which may be a thermistor, continually senses the atmospheric temperature and creates, in accordance therewith, a variable output volton conductor 76, equivalent to a. difference -of 4.0 F. and

age signal, 1",, on conductor means 70 so as to apply such signal to comparator 68.

Humidity transducer 34, which is of the differential type, that is, a differential humidity transducer, responds to the difference between dew point and ambient temperature and creates in accordance therewith a variable voltage signal, V on conductor means 72 thereby applying such signal to a third comparator 74. The other side of comparator 74 has applied thereto, as by conductor means 76, a variable voltage signal, V created as an output by comparator 68.

Conductor means 78 and 80 respectively operatively connected to

comparators

60 and 74 are each connected to suitable logic circuitry or logic device 82 which, in this instance, may be a NOR logic. As will become apparent,

comparators

60 and 74 will at times respectively produce output signals, V and V' on conductors 78 and 80 so as to apply such signals to logic device 82. When such signals are simultaneously received by logic device 82, the device 82 creates an output signal, V directed via conductor means 84 to associated actuator means 38 in order to achieve energization thereof.

OPERATION Let it now be assumed that engine 10 is in operation, switch 48 closed, and surface temperature reference potentiometer 30 adjusted and set so as to create voltage signal T of a magnitude indicative of 32 F.

It is further assumed that because of such phenomena as the venturi effect of the air flowing through the intake throat of the engine 10, that the temperature of throat surface 28 will progressively decrease. As the thermistor or surface temperature transducer 25 senses such changes in temperature of throat surface 28, thermistor 25 creates output voltage signal, T of a magnitude reflective of the then existing temperature of surface 28.

When signal T finally indicates that surface 28 has attained a temperature equivalent to that established by the reference potentiometer 30, which in this case is assumed to be 32 F., comparator 60 senses the equality between signals T and T and in response thereto creates output voltage signal V on conductor 78 and applies it to logic device 82. However, this single signal V will not command the logic device 82 to produce the final output signal or actuating voltage V because the logic device 82 requires the simultaneous presence of both signals V and V',, before it will produce output V The same signal, T is applied to comparator 68 by means of conductor 66. The other side of comparator 68 has applied thereto the variable signal, T created by the ambient temperature transducer 32, reflective of the actual ambient temperature. Preferably, comparator 68 is a differential amplifier which will amplify'the difference between the signals T and T and create an output signal, V proportional to such difference; however, comparator or amplifier 68 will only amplify the difference if the signal T; from surface temperature thermistor 25 is less than the signal T created by ambient temperature transducer 32.

apply it as an input signal to a third comparator 74 which, preferably is alsoadifferential amplifieij.

As previously stated humidity transducer 34 continually creates an output signal, V indicative of, the difference between dew point and ambient temperatures. This signal, V

is applied to comparator 74 via conductor means 72. When signal V is reflective of a difference. of 4.0" F, then both signals V and V are equal to each other and comparator 74 will then produce or create the second output signal V' on conductor and apply it to the logic device 82. As previously discussed, the simultaneous presence of signals V and V' on logic means 82 results in the creation of final output signal V for energizing appropriate actuator means 38.

From the preceding, it should be apparent that comparator 74 determines when the surface 28 is actually at dew point. That is, first, comparator 68 creates a signal, V which may be described in the following manner:

V (ambient temperature) (surface 28 temperature) while differential humidity transducer 34 creates a signal, V which may be described in the following manner:

V,,'= (ambient temperature) (dew point) Accordingly, it can be seen that in each of the above equations, the ambient temperature" values are equal to each other; therefore, when signal V is equal to signal V it means that surface 28 temperature must be equal to dew point (as defined herein).

Therefore, when both signals V and V are present both icing conditions are existent; that is, the monitored surface 28 is at a temperature of at least 32 F. and the surface 28 is at dew point.

Actuator means 38, upon being energized, may in turn cause actuation of related control means such as at 40 (FIG. 1) for causing valve 20 to move to a more fully closed position and valve 26 to move to a more fully opened position. In such case, the heated exhaust gases will be communicated via conduitry 16 and 24 to the intake plenum 22 and intake 12 thereby heating the surface 28 of the intake throat in order to prevent any frost formation or icing buildup on such surface.

Other suitable related devices such as 42 may be actuated as by means of mechanical or electrical transmission means and 92. A

The invention has been described with reference to its use in combination with a stationary power plant turbine engine 10. However, it should be apparent that the invention is not limited to use in combination with such an engine and that the invention may be employed with reference to any surface to be monitored and protected from frost and ice formation.

One of the major advantages of this invention is its extreme accuracy in detecting icing conditions. This, of course, is accomplished through analog comparison of psychrometric parameters and exact digital switching when certain of such parameters exist.

In view of the preceding, it can be seen that, contrary to the prior art, heated exhaust gases are not delivered to the engine air intake 12 until such time as such gases are actually needed in order to prevent frost or ice formation. This, of course, results in not only increased engine efficiency, in comparison to prior art devices, but also extended engine life.

Although only one preferred embodiment of the invention has been disclosed and described, it is apparent that-other embodiments and modifications of the invention are possible withinthe scope of the appended claims.

Whatl claim as my invention is: 4

1. Apparatus .for detecting icing conditions on a surface, said apparatus comprising first means for creating a first output signal indicating that said surface has attained a temperature equivalent to a predetermined temperature, second means for creating a second output signal indicating that said temperature of said surface is equivalent to dew point, and third means responsive to said first and second output signals for causing actuation of related output means, said first means comprising temperature responsive transducer means responsive to said temperature of said surface and effective for producing a variable signal in accordance therewith, reference signal producing means effective for creating a reference signal indicative of said predetermined temperature, and comparator means for receiving said variable signal and said reference signal, said comparator means being effective to create said first output signal when said variable signal and said reference signal collectively indicate that said temperature of said surface and said predetermined temperature are equal to each other, said second means comprising fourth means effective for both sensing ambient temperature and creating a first variable signal in accordance with the difference between said temperature of said surface and said ambient temperature, humidity responsive transducer means effective for sensing relative ambient humidity and creating a second variable signal in accordance with the difierence between said ambient temperature and dew point, and first comparator means for receiving said first and second variable signals, said first comparator means being effective to create said second output signal when said first and second variable signals are equal to each other.

2. Apparatus according to claim 1 wherein said related output means comprises means for applying heat to said surface in order to raise said temperature of said surface above said predetermined temperature value.

3. Apparatus according to claim 1 wherein said temperature responsive transducer means comprises a thermistor, and wherein said reference signal producing means comprises a potentiometer.

4. Apparatus according to claim 1 wherein said temperature responsive transducer means comprises a thermistor, wherein said reference signal producing means comprises a potentiometer, and wherein said comparator comprises a differential amplifier.

5. Apparatus according to claim 1 wherein said humidity responsive transducer means comprises a differential humidity transducer continually responsive to the difference between dew point and said ambient temperature, and wherein said first comparator means comprises a differential amplifier.

6. Apparatus according to claim 1 wherein said fourth means comprises temperature responsive transducer means responsive to ambient temperature and effective for creating a first variable parameter signal in accordance therewith,

second comparator means adapted to receive said first variable parameter signal and a second signal indicative of the temperature of said surface, said second comparator being effective to create said first variable signal in accordance with the difference between said first variable parameter signal and said second signal.

7. Apparatus according to claim 1 wherein said fourth means comprises temperature responsive transducer means responsive to ambient temperature and effective for creating a first variable parameter signal in accordance therewith, second comparator means adapted to receive said first'varia: ble parameter signal and a second signal indicative of the temperature of said surface, said second comparator being effective to create said first variable signal in accordance with the difi'erence between said first variable parameter signal and said second signal, wherein said humidity responsive transducer means comprises a differential humidity transducer continually responsive to the difference between dew point and said ambient temperature, and wherein said first comparator means comprises a differential amplifier.

8. Apparatus according to claim 1 wherein said first means comprises temperature responsive thermistor means responsive to said temperature of said surface and effective for producing a first variable signal in accordance therewith, an

adjustable potentiometer effective for creating a reference signal indicative of said predetermined temperature, and first comparator means comprising differential amplifier means for receiving said first variable signal and said reference signal, said differential amplifier means being effective to create said first output signal when said first variable signal and said reference signal collectively indicate that said temperature of said surface and said predetermined temperature are equal to each other, wherein said second means comprises second temperature responsive thermistor means responsive to ambient temperature and effective for creating a second variable parameter signal in accordance therewith, second comparator means adapted to receive said second variable signal and said first variable signal, said second comparator being effective to create a third variable signal in accordance with the difference between said first and second variable signals, a differential humidity transducer continually responsive to the difference between ambient temperature and dew point and effective to create a fourth variable signal in accordance therewith, third comparator means responsive to said third and fourth variable signals and effective to create said second output signal when said third and fourth variable signals are equal to each other, and wherein said third means comprises NOR logic circuitry.

Claims

1. Apparatus for detecting icing conditions on a surface, said apparatus comprising first means for creating a first output signal indicating that said surface has attained a temperature equivalent to a predetermined temperature, second means for creating a second output signal indicating that said temperature of said surface is equivalent to dew point, and third means responsive to said first and second output signals for causing actuation of related output means, said first means comprising temperature responsive transducer means responsive to said temperature of said surface and effective for producing a variable signal in accordance therewith, reference signal producing means effective for creating a reference signal indicative of said predetermined temperature, and comparator means for receiving said variable signal and said reference signal, said comparator means being effective to create said first output signal when said variable signal and said reference signal collectively indicate that said temperature of said surface and said predetermined temperature are equal to each other, said second means comprising fourth means effective for both sensing ambient temperature and creating a first variable signal in accordance with the difference between said temperature of said surface and said ambient temperature, humidity responsive transducer means effective for sensing relative ambient humidity and creating a second variable signal in accordance with the difference between said ambient temperature and dew point, and first comparator means for receiving said first and second variable signals, said first comparator means being effective to create said second output signal when said first and second variable signals are equal to each other.

6. Apparatus according to claim 1 wherein said fourth means comprises temperature responsive transducer means responsive to ambient temperature and effective for creating a first variable parameter signal in accordance therewith, Second comparator means adapted to receive said first variable parameter signal and a second signal indicative of the temperature of said surface, said second comparator being effective to create said first variable signal in accordance with the difference between said first variable parameter signal and said second signal.

7. Apparatus according to claim 1 wherein said fourth means comprises temperature responsive transducer means responsive to ambient temperature and effective for creating a first variable parameter signal in accordance therewith, second comparator means adapted to receive said first variable parameter signal and a second signal indicative of the temperature of said surface, said second comparator being effective to create said first variable signal in accordance with the difference between said first variable parameter signal and said second signal, wherein said humidity responsive transducer means comprises a differential humidity transducer continually responsive to the difference between dew point and said ambient temperature, and wherein said first comparator means comprises a differential amplifier.

8. Apparatus according to claim 1 wherein said first means comprises temperature responsive thermistor means responsive to said temperature of said surface and effective for producing a first variable signal in accordance therewith, an adjustable potentiometer effective for creating a reference signal indicative of said predetermined temperature, and first comparator means comprising differential amplifier means for receiving said first variable signal and said reference signal, said differential amplifier means being effective to create said first output signal when said first variable signal and said reference signal collectively indicate that said temperature of said surface and said predetermined temperature are equal to each other, wherein said second means comprises second temperature responsive thermistor means responsive to ambient temperature and effective for creating a second variable parameter signal in accordance therewith, second comparator means adapted to receive said second variable signal and said first variable signal, said second comparator being effective to create a third variable signal in accordance with the difference between said first and second variable signals, a differential humidity transducer continually responsive to the difference between ambient temperature and dew point and effective to create a fourth variable signal in accordance therewith, third comparator means responsive to said third and fourth variable signals and effective to create said second output signal when said third and fourth variable signals are equal to each other, and wherein said third means comprises NOR logic circuitry.