In a Spin are Both Wings Stalled?












4












$begingroup$


I missed a test question which asked that if an airplane was spinning to the left which wing was stalled. The supposed correct answer was that both wings are stalled (I had answered that the left wing only was stalled). However after looking at the this article on Wikipedia it seems to indicate that only one wing needs to be stalled to spin:




In a normal spin, the wing on the inside of the turn stalls while the outside wing remains flying. It is possible for both wings to stall, but the angle of attack of each wing, and consequently its lift and drag, are different. Either situation causes the aircraft to autorotate toward the stalled wing due to its higher drag and loss of lift.




So my question is was it fair for me to have missed that test question since according to Wikipedia a spin can occur with only one wing stalled?










share|improve this question









$endgroup$

















    4












    $begingroup$


    I missed a test question which asked that if an airplane was spinning to the left which wing was stalled. The supposed correct answer was that both wings are stalled (I had answered that the left wing only was stalled). However after looking at the this article on Wikipedia it seems to indicate that only one wing needs to be stalled to spin:




    In a normal spin, the wing on the inside of the turn stalls while the outside wing remains flying. It is possible for both wings to stall, but the angle of attack of each wing, and consequently its lift and drag, are different. Either situation causes the aircraft to autorotate toward the stalled wing due to its higher drag and loss of lift.




    So my question is was it fair for me to have missed that test question since according to Wikipedia a spin can occur with only one wing stalled?










    share|improve this question









    $endgroup$















      4












      4








      4





      $begingroup$


      I missed a test question which asked that if an airplane was spinning to the left which wing was stalled. The supposed correct answer was that both wings are stalled (I had answered that the left wing only was stalled). However after looking at the this article on Wikipedia it seems to indicate that only one wing needs to be stalled to spin:




      In a normal spin, the wing on the inside of the turn stalls while the outside wing remains flying. It is possible for both wings to stall, but the angle of attack of each wing, and consequently its lift and drag, are different. Either situation causes the aircraft to autorotate toward the stalled wing due to its higher drag and loss of lift.




      So my question is was it fair for me to have missed that test question since according to Wikipedia a spin can occur with only one wing stalled?










      share|improve this question









      $endgroup$




      I missed a test question which asked that if an airplane was spinning to the left which wing was stalled. The supposed correct answer was that both wings are stalled (I had answered that the left wing only was stalled). However after looking at the this article on Wikipedia it seems to indicate that only one wing needs to be stalled to spin:




      In a normal spin, the wing on the inside of the turn stalls while the outside wing remains flying. It is possible for both wings to stall, but the angle of attack of each wing, and consequently its lift and drag, are different. Either situation causes the aircraft to autorotate toward the stalled wing due to its higher drag and loss of lift.




      So my question is was it fair for me to have missed that test question since according to Wikipedia a spin can occur with only one wing stalled?







      spins faa-knowledge-test






      share|improve this question













      share|improve this question











      share|improve this question




      share|improve this question










      asked 6 hours ago









      DLHDLH

      2,598829




      2,598829






















          4 Answers
          4






          active

          oldest

          votes


















          4












          $begingroup$

          No, one wing has at least partially attached flow. How else would there be a rolling and yawing moment which keeps the spin movement alive?



          During a spin the aircraft experiences a linear variation in angle of attack over span. The pitch attitude is between 40° and 60° nose-down, and the local angle of attack is 90° minus the pitch angle, which is between 50° and 30°, at the center wing. Move outward from there and the angle of attack increases on the retarding side and decreases on the advancing side.



          As a consequence, the outer advancing wing will experience a moderate angle of attack which can even become negative at the tip. Therefore, a sizeable portion of that wing side has attached flow with high lift and low drag. On the other side the angle of attack grows to 90° and beyond, so the wing is fully separated and the aerodynamic force is normal to the wing surface. See below for a diagram of the flow direction: The dark blue vector is from the falling motion and the red vector is the product of the yawing moment $omega_z$ times the wing station y. Together they combine to the green vector which produces a resulting aerodynamic force R:



          flow over a spinning wing



          On the left is the retarding wing and on the right the advancing wing. Note that the aerodynamic force is in line with the flow vector on the retarding wing with its fully separated flow while the aerodynamic force is normal to the flow vector due to the attached flow on the advancing wing. The difference in the local forces produces a yawing and rolling moment which balances with the damping forces. If there would not be such an asymmetry, the motion would die down quickly.



          Even in a flat spin, where the pitch attitude is around 0° (resulting in 90° angle of attack at the center wing), the advancing side of a moderate to high aspect ratio wing produces some nose thrust from partially attached flow. How else would the aircraft keep spinnig? Low aspect ratio designs produce a propelling nose vortex on the forward fuselage which keeps the motion alive.






          share|improve this answer











          $endgroup$













          • $begingroup$
            So this is kind of like a helicopter rotor retreating blade stall where the retreating side can stall due to higher angle of attack?
            $endgroup$
            – DLH
            4 hours ago










          • $begingroup$
            @DLH: In a way, yes. But not cyclic, which causes all kind of funny oscillations from hysteresis on helicopter blades.
            $endgroup$
            – Peter Kämpf
            4 hours ago










          • $begingroup$
            The argument that at least one wing has partially attached flow is meaningless. The question is, is the wing as a whole exhibiting the behavior in the plot I used. Airplanes stall all the time with portions of the wing unstalled. That’s why we twist the wing aero or geometrically, to keep roll control “post stall”.
            $endgroup$
            – MikeY
            4 hours ago








          • 1




            $begingroup$
            @MikeY: I believe that you are referencing washout which means the root of the wing will stall before the tip and this is used to keep some roll stability in the stall. However I believe the situation Peter presents here is that the tip stalls before the root.
            $endgroup$
            – DLH
            3 hours ago






          • 1




            $begingroup$
            "How else would there be a rolling and yawing moment which keeps the spin movement alive?" Rhetorical questions are unbecoming, Peter! :)
            $endgroup$
            – Fattie
            3 hours ago



















          4












          $begingroup$

          Yes, both are stalled.



          I guess a nit-pick is on "what is stalled"? I adopt that you are at or beyond the point that an increase in AOA results in an increase in lift. That's the top of the blue curve in the plot below.



          At low angles of attack (AOA) planes are naturally stable in roll. The downgoing wing sees a higher AOA which results in more lift, and a restoring force. The upgoing wings sees a lower AOA, and less lift, so it is stabilizing too.



          At a high AOA, though, you are operating on the backside of the wing lift diagram. In the picture below, this would be at and beyond 20 degrees AOA.



          enter image description here



          Now, the upgoing wing sees more lift, which leads to positively reinforcing going up. Same but opposite on the downgoing. It sees less lift.



          Also, the red line shows drag. That downgoing wing (on inside of the spin) sees a great increase in drag, which will lead to a yaw towards that wing, i.e., pro-spin.



          So to get in the situation where a roll/yaw movement is positively reinforcing, you need to be in stalled AOA. You might start with just one wing, you'll get to both.



          JMHO!



          EDIT



          Here’s a NASA video of a wing with tufts when it is both on the inside of the spin and outside. Stalled in both (but different airflow).











          share|improve this answer











          $endgroup$









          • 2




            $begingroup$
            I think this is a good answer. I've been reading up on spins. While I think that maybe only one wing will stall during the departure phase of the spin, by the time the spin is in the developed stage both wings will be stalled. I think the test question could have been better worded though.
            $endgroup$
            – DLH
            4 hours ago






          • 1




            $begingroup$
            @DLH I think this is a poor answer because it is wrong.
            $endgroup$
            – Peter Kämpf
            4 hours ago












          • $begingroup$
            @PeterKämpf: Oh man I wish you had answered sooner, I was persuaded.
            $endgroup$
            – DLH
            4 hours ago










          • $begingroup$
            In your answer, you ask, "What is stalled?" Good question. So have you defined what you are considering stalled to mean for the purpose of the answer? Some people will think of stalled to mean something like, "not generating enough lift to oppose the force of weight". The technical answer is exceeding the critical angle of attack.
            $endgroup$
            – Ryan Mortensen
            3 mins ago





















          2












          $begingroup$

          A spin is an autorotation that requires an asymmetric thrust force to sustain. This requires the wing span to be anchored at one end by drag, with the other end developing enough thrust to overcome the (rather weak) stabilizing force of the vertical fin and drive that end forward, rotating the plane. The AOA is highest at the inboard end and decreases as you move outboard due to the higher forward velocity. At some point along the span, the outer end is unstalled or only semi-stalled and is making at least some amount of lift/thrust.






          share|improve this answer









          $endgroup$





















            0












            $begingroup$

            This "test" question may apply to a certain type of aircraft and spin procedure (Cessna 172) that has to be stalled straightforward (there for both wings stalled), followed by the "wrong" inputs (rudder into spin, ailerons away) to make it spin. The important concept is that differences in drag and lift between the 2 wings, whether one is stalled or not, keeps the plane in a self sustaining yaw/slip.



            Important is the role of the V stab/rudder in maintaining or ending the spin. Looking at a simple cup shaped anomometer helps visualize the effects of pro-spin rudder into the spin and anti-spin rudder away. Stopping yaw with opposite rudder is key to breaking a spin, and controlling yaw is key to not entering one.



            Also key is how uncoordinated aileron input, trying to roll away from a turn, can cause a spin.
            (The "inside" slower wing is now compounded with the down aileron creating a higher AOA).
            Although aileron roll effect can reverse in the stall AOA regime, rudder will not. But this also means that applying opposite ailerons in a spin can be explored! (Qualified instructor recommended).



            But for the 172, just letting go of the yoke, power to idle, and opposite rudder would break the spin if CG was correct.



            Every plane and situation is different (as seen by these answers), it is advisable to find out how your plane handles and how to control it, no matter what the "correct" test answer is.






            share|improve this answer











            $endgroup$














              Your Answer





              StackExchange.ifUsing("editor", function () {
              return StackExchange.using("mathjaxEditing", function () {
              StackExchange.MarkdownEditor.creationCallbacks.add(function (editor, postfix) {
              StackExchange.mathjaxEditing.prepareWmdForMathJax(editor, postfix, [["$", "$"], ["\\(","\\)"]]);
              });
              });
              }, "mathjax-editing");

              StackExchange.ready(function() {
              var channelOptions = {
              tags: "".split(" "),
              id: "528"
              };
              initTagRenderer("".split(" "), "".split(" "), channelOptions);

              StackExchange.using("externalEditor", function() {
              // Have to fire editor after snippets, if snippets enabled
              if (StackExchange.settings.snippets.snippetsEnabled) {
              StackExchange.using("snippets", function() {
              createEditor();
              });
              }
              else {
              createEditor();
              }
              });

              function createEditor() {
              StackExchange.prepareEditor({
              heartbeatType: 'answer',
              autoActivateHeartbeat: false,
              convertImagesToLinks: false,
              noModals: true,
              showLowRepImageUploadWarning: true,
              reputationToPostImages: null,
              bindNavPrevention: true,
              postfix: "",
              imageUploader: {
              brandingHtml: "Powered by u003ca class="icon-imgur-white" href="https://imgur.com/"u003eu003c/au003e",
              contentPolicyHtml: "User contributions licensed under u003ca href="https://creativecommons.org/licenses/by-sa/3.0/"u003ecc by-sa 3.0 with attribution requiredu003c/au003e u003ca href="https://stackoverflow.com/legal/content-policy"u003e(content policy)u003c/au003e",
              allowUrls: true
              },
              noCode: true, onDemand: true,
              discardSelector: ".discard-answer"
              ,immediatelyShowMarkdownHelp:true
              });


              }
              });














              draft saved

              draft discarded


















              StackExchange.ready(
              function () {
              StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2faviation.stackexchange.com%2fquestions%2f62020%2fin-a-spin-are-both-wings-stalled%23new-answer', 'question_page');
              }
              );

              Post as a guest















              Required, but never shown

























              4 Answers
              4






              active

              oldest

              votes








              4 Answers
              4






              active

              oldest

              votes









              active

              oldest

              votes






              active

              oldest

              votes









              4












              $begingroup$

              No, one wing has at least partially attached flow. How else would there be a rolling and yawing moment which keeps the spin movement alive?



              During a spin the aircraft experiences a linear variation in angle of attack over span. The pitch attitude is between 40° and 60° nose-down, and the local angle of attack is 90° minus the pitch angle, which is between 50° and 30°, at the center wing. Move outward from there and the angle of attack increases on the retarding side and decreases on the advancing side.



              As a consequence, the outer advancing wing will experience a moderate angle of attack which can even become negative at the tip. Therefore, a sizeable portion of that wing side has attached flow with high lift and low drag. On the other side the angle of attack grows to 90° and beyond, so the wing is fully separated and the aerodynamic force is normal to the wing surface. See below for a diagram of the flow direction: The dark blue vector is from the falling motion and the red vector is the product of the yawing moment $omega_z$ times the wing station y. Together they combine to the green vector which produces a resulting aerodynamic force R:



              flow over a spinning wing



              On the left is the retarding wing and on the right the advancing wing. Note that the aerodynamic force is in line with the flow vector on the retarding wing with its fully separated flow while the aerodynamic force is normal to the flow vector due to the attached flow on the advancing wing. The difference in the local forces produces a yawing and rolling moment which balances with the damping forces. If there would not be such an asymmetry, the motion would die down quickly.



              Even in a flat spin, where the pitch attitude is around 0° (resulting in 90° angle of attack at the center wing), the advancing side of a moderate to high aspect ratio wing produces some nose thrust from partially attached flow. How else would the aircraft keep spinnig? Low aspect ratio designs produce a propelling nose vortex on the forward fuselage which keeps the motion alive.






              share|improve this answer











              $endgroup$













              • $begingroup$
                So this is kind of like a helicopter rotor retreating blade stall where the retreating side can stall due to higher angle of attack?
                $endgroup$
                – DLH
                4 hours ago










              • $begingroup$
                @DLH: In a way, yes. But not cyclic, which causes all kind of funny oscillations from hysteresis on helicopter blades.
                $endgroup$
                – Peter Kämpf
                4 hours ago










              • $begingroup$
                The argument that at least one wing has partially attached flow is meaningless. The question is, is the wing as a whole exhibiting the behavior in the plot I used. Airplanes stall all the time with portions of the wing unstalled. That’s why we twist the wing aero or geometrically, to keep roll control “post stall”.
                $endgroup$
                – MikeY
                4 hours ago








              • 1




                $begingroup$
                @MikeY: I believe that you are referencing washout which means the root of the wing will stall before the tip and this is used to keep some roll stability in the stall. However I believe the situation Peter presents here is that the tip stalls before the root.
                $endgroup$
                – DLH
                3 hours ago






              • 1




                $begingroup$
                "How else would there be a rolling and yawing moment which keeps the spin movement alive?" Rhetorical questions are unbecoming, Peter! :)
                $endgroup$
                – Fattie
                3 hours ago
















              4












              $begingroup$

              No, one wing has at least partially attached flow. How else would there be a rolling and yawing moment which keeps the spin movement alive?



              During a spin the aircraft experiences a linear variation in angle of attack over span. The pitch attitude is between 40° and 60° nose-down, and the local angle of attack is 90° minus the pitch angle, which is between 50° and 30°, at the center wing. Move outward from there and the angle of attack increases on the retarding side and decreases on the advancing side.



              As a consequence, the outer advancing wing will experience a moderate angle of attack which can even become negative at the tip. Therefore, a sizeable portion of that wing side has attached flow with high lift and low drag. On the other side the angle of attack grows to 90° and beyond, so the wing is fully separated and the aerodynamic force is normal to the wing surface. See below for a diagram of the flow direction: The dark blue vector is from the falling motion and the red vector is the product of the yawing moment $omega_z$ times the wing station y. Together they combine to the green vector which produces a resulting aerodynamic force R:



              flow over a spinning wing



              On the left is the retarding wing and on the right the advancing wing. Note that the aerodynamic force is in line with the flow vector on the retarding wing with its fully separated flow while the aerodynamic force is normal to the flow vector due to the attached flow on the advancing wing. The difference in the local forces produces a yawing and rolling moment which balances with the damping forces. If there would not be such an asymmetry, the motion would die down quickly.



              Even in a flat spin, where the pitch attitude is around 0° (resulting in 90° angle of attack at the center wing), the advancing side of a moderate to high aspect ratio wing produces some nose thrust from partially attached flow. How else would the aircraft keep spinnig? Low aspect ratio designs produce a propelling nose vortex on the forward fuselage which keeps the motion alive.






              share|improve this answer











              $endgroup$













              • $begingroup$
                So this is kind of like a helicopter rotor retreating blade stall where the retreating side can stall due to higher angle of attack?
                $endgroup$
                – DLH
                4 hours ago










              • $begingroup$
                @DLH: In a way, yes. But not cyclic, which causes all kind of funny oscillations from hysteresis on helicopter blades.
                $endgroup$
                – Peter Kämpf
                4 hours ago










              • $begingroup$
                The argument that at least one wing has partially attached flow is meaningless. The question is, is the wing as a whole exhibiting the behavior in the plot I used. Airplanes stall all the time with portions of the wing unstalled. That’s why we twist the wing aero or geometrically, to keep roll control “post stall”.
                $endgroup$
                – MikeY
                4 hours ago








              • 1




                $begingroup$
                @MikeY: I believe that you are referencing washout which means the root of the wing will stall before the tip and this is used to keep some roll stability in the stall. However I believe the situation Peter presents here is that the tip stalls before the root.
                $endgroup$
                – DLH
                3 hours ago






              • 1




                $begingroup$
                "How else would there be a rolling and yawing moment which keeps the spin movement alive?" Rhetorical questions are unbecoming, Peter! :)
                $endgroup$
                – Fattie
                3 hours ago














              4












              4








              4





              $begingroup$

              No, one wing has at least partially attached flow. How else would there be a rolling and yawing moment which keeps the spin movement alive?



              During a spin the aircraft experiences a linear variation in angle of attack over span. The pitch attitude is between 40° and 60° nose-down, and the local angle of attack is 90° minus the pitch angle, which is between 50° and 30°, at the center wing. Move outward from there and the angle of attack increases on the retarding side and decreases on the advancing side.



              As a consequence, the outer advancing wing will experience a moderate angle of attack which can even become negative at the tip. Therefore, a sizeable portion of that wing side has attached flow with high lift and low drag. On the other side the angle of attack grows to 90° and beyond, so the wing is fully separated and the aerodynamic force is normal to the wing surface. See below for a diagram of the flow direction: The dark blue vector is from the falling motion and the red vector is the product of the yawing moment $omega_z$ times the wing station y. Together they combine to the green vector which produces a resulting aerodynamic force R:



              flow over a spinning wing



              On the left is the retarding wing and on the right the advancing wing. Note that the aerodynamic force is in line with the flow vector on the retarding wing with its fully separated flow while the aerodynamic force is normal to the flow vector due to the attached flow on the advancing wing. The difference in the local forces produces a yawing and rolling moment which balances with the damping forces. If there would not be such an asymmetry, the motion would die down quickly.



              Even in a flat spin, where the pitch attitude is around 0° (resulting in 90° angle of attack at the center wing), the advancing side of a moderate to high aspect ratio wing produces some nose thrust from partially attached flow. How else would the aircraft keep spinnig? Low aspect ratio designs produce a propelling nose vortex on the forward fuselage which keeps the motion alive.






              share|improve this answer











              $endgroup$



              No, one wing has at least partially attached flow. How else would there be a rolling and yawing moment which keeps the spin movement alive?



              During a spin the aircraft experiences a linear variation in angle of attack over span. The pitch attitude is between 40° and 60° nose-down, and the local angle of attack is 90° minus the pitch angle, which is between 50° and 30°, at the center wing. Move outward from there and the angle of attack increases on the retarding side and decreases on the advancing side.



              As a consequence, the outer advancing wing will experience a moderate angle of attack which can even become negative at the tip. Therefore, a sizeable portion of that wing side has attached flow with high lift and low drag. On the other side the angle of attack grows to 90° and beyond, so the wing is fully separated and the aerodynamic force is normal to the wing surface. See below for a diagram of the flow direction: The dark blue vector is from the falling motion and the red vector is the product of the yawing moment $omega_z$ times the wing station y. Together they combine to the green vector which produces a resulting aerodynamic force R:



              flow over a spinning wing



              On the left is the retarding wing and on the right the advancing wing. Note that the aerodynamic force is in line with the flow vector on the retarding wing with its fully separated flow while the aerodynamic force is normal to the flow vector due to the attached flow on the advancing wing. The difference in the local forces produces a yawing and rolling moment which balances with the damping forces. If there would not be such an asymmetry, the motion would die down quickly.



              Even in a flat spin, where the pitch attitude is around 0° (resulting in 90° angle of attack at the center wing), the advancing side of a moderate to high aspect ratio wing produces some nose thrust from partially attached flow. How else would the aircraft keep spinnig? Low aspect ratio designs produce a propelling nose vortex on the forward fuselage which keeps the motion alive.







              share|improve this answer














              share|improve this answer



              share|improve this answer








              edited 4 hours ago

























              answered 4 hours ago









              Peter KämpfPeter Kämpf

              161k12411654




              161k12411654












              • $begingroup$
                So this is kind of like a helicopter rotor retreating blade stall where the retreating side can stall due to higher angle of attack?
                $endgroup$
                – DLH
                4 hours ago










              • $begingroup$
                @DLH: In a way, yes. But not cyclic, which causes all kind of funny oscillations from hysteresis on helicopter blades.
                $endgroup$
                – Peter Kämpf
                4 hours ago










              • $begingroup$
                The argument that at least one wing has partially attached flow is meaningless. The question is, is the wing as a whole exhibiting the behavior in the plot I used. Airplanes stall all the time with portions of the wing unstalled. That’s why we twist the wing aero or geometrically, to keep roll control “post stall”.
                $endgroup$
                – MikeY
                4 hours ago








              • 1




                $begingroup$
                @MikeY: I believe that you are referencing washout which means the root of the wing will stall before the tip and this is used to keep some roll stability in the stall. However I believe the situation Peter presents here is that the tip stalls before the root.
                $endgroup$
                – DLH
                3 hours ago






              • 1




                $begingroup$
                "How else would there be a rolling and yawing moment which keeps the spin movement alive?" Rhetorical questions are unbecoming, Peter! :)
                $endgroup$
                – Fattie
                3 hours ago


















              • $begingroup$
                So this is kind of like a helicopter rotor retreating blade stall where the retreating side can stall due to higher angle of attack?
                $endgroup$
                – DLH
                4 hours ago










              • $begingroup$
                @DLH: In a way, yes. But not cyclic, which causes all kind of funny oscillations from hysteresis on helicopter blades.
                $endgroup$
                – Peter Kämpf
                4 hours ago










              • $begingroup$
                The argument that at least one wing has partially attached flow is meaningless. The question is, is the wing as a whole exhibiting the behavior in the plot I used. Airplanes stall all the time with portions of the wing unstalled. That’s why we twist the wing aero or geometrically, to keep roll control “post stall”.
                $endgroup$
                – MikeY
                4 hours ago








              • 1




                $begingroup$
                @MikeY: I believe that you are referencing washout which means the root of the wing will stall before the tip and this is used to keep some roll stability in the stall. However I believe the situation Peter presents here is that the tip stalls before the root.
                $endgroup$
                – DLH
                3 hours ago






              • 1




                $begingroup$
                "How else would there be a rolling and yawing moment which keeps the spin movement alive?" Rhetorical questions are unbecoming, Peter! :)
                $endgroup$
                – Fattie
                3 hours ago
















              $begingroup$
              So this is kind of like a helicopter rotor retreating blade stall where the retreating side can stall due to higher angle of attack?
              $endgroup$
              – DLH
              4 hours ago




              $begingroup$
              So this is kind of like a helicopter rotor retreating blade stall where the retreating side can stall due to higher angle of attack?
              $endgroup$
              – DLH
              4 hours ago












              $begingroup$
              @DLH: In a way, yes. But not cyclic, which causes all kind of funny oscillations from hysteresis on helicopter blades.
              $endgroup$
              – Peter Kämpf
              4 hours ago




              $begingroup$
              @DLH: In a way, yes. But not cyclic, which causes all kind of funny oscillations from hysteresis on helicopter blades.
              $endgroup$
              – Peter Kämpf
              4 hours ago












              $begingroup$
              The argument that at least one wing has partially attached flow is meaningless. The question is, is the wing as a whole exhibiting the behavior in the plot I used. Airplanes stall all the time with portions of the wing unstalled. That’s why we twist the wing aero or geometrically, to keep roll control “post stall”.
              $endgroup$
              – MikeY
              4 hours ago






              $begingroup$
              The argument that at least one wing has partially attached flow is meaningless. The question is, is the wing as a whole exhibiting the behavior in the plot I used. Airplanes stall all the time with portions of the wing unstalled. That’s why we twist the wing aero or geometrically, to keep roll control “post stall”.
              $endgroup$
              – MikeY
              4 hours ago






              1




              1




              $begingroup$
              @MikeY: I believe that you are referencing washout which means the root of the wing will stall before the tip and this is used to keep some roll stability in the stall. However I believe the situation Peter presents here is that the tip stalls before the root.
              $endgroup$
              – DLH
              3 hours ago




              $begingroup$
              @MikeY: I believe that you are referencing washout which means the root of the wing will stall before the tip and this is used to keep some roll stability in the stall. However I believe the situation Peter presents here is that the tip stalls before the root.
              $endgroup$
              – DLH
              3 hours ago




              1




              1




              $begingroup$
              "How else would there be a rolling and yawing moment which keeps the spin movement alive?" Rhetorical questions are unbecoming, Peter! :)
              $endgroup$
              – Fattie
              3 hours ago




              $begingroup$
              "How else would there be a rolling and yawing moment which keeps the spin movement alive?" Rhetorical questions are unbecoming, Peter! :)
              $endgroup$
              – Fattie
              3 hours ago











              4












              $begingroup$

              Yes, both are stalled.



              I guess a nit-pick is on "what is stalled"? I adopt that you are at or beyond the point that an increase in AOA results in an increase in lift. That's the top of the blue curve in the plot below.



              At low angles of attack (AOA) planes are naturally stable in roll. The downgoing wing sees a higher AOA which results in more lift, and a restoring force. The upgoing wings sees a lower AOA, and less lift, so it is stabilizing too.



              At a high AOA, though, you are operating on the backside of the wing lift diagram. In the picture below, this would be at and beyond 20 degrees AOA.



              enter image description here



              Now, the upgoing wing sees more lift, which leads to positively reinforcing going up. Same but opposite on the downgoing. It sees less lift.



              Also, the red line shows drag. That downgoing wing (on inside of the spin) sees a great increase in drag, which will lead to a yaw towards that wing, i.e., pro-spin.



              So to get in the situation where a roll/yaw movement is positively reinforcing, you need to be in stalled AOA. You might start with just one wing, you'll get to both.



              JMHO!



              EDIT



              Here’s a NASA video of a wing with tufts when it is both on the inside of the spin and outside. Stalled in both (but different airflow).











              share|improve this answer











              $endgroup$









              • 2




                $begingroup$
                I think this is a good answer. I've been reading up on spins. While I think that maybe only one wing will stall during the departure phase of the spin, by the time the spin is in the developed stage both wings will be stalled. I think the test question could have been better worded though.
                $endgroup$
                – DLH
                4 hours ago






              • 1




                $begingroup$
                @DLH I think this is a poor answer because it is wrong.
                $endgroup$
                – Peter Kämpf
                4 hours ago












              • $begingroup$
                @PeterKämpf: Oh man I wish you had answered sooner, I was persuaded.
                $endgroup$
                – DLH
                4 hours ago










              • $begingroup$
                In your answer, you ask, "What is stalled?" Good question. So have you defined what you are considering stalled to mean for the purpose of the answer? Some people will think of stalled to mean something like, "not generating enough lift to oppose the force of weight". The technical answer is exceeding the critical angle of attack.
                $endgroup$
                – Ryan Mortensen
                3 mins ago


















              4












              $begingroup$

              Yes, both are stalled.



              I guess a nit-pick is on "what is stalled"? I adopt that you are at or beyond the point that an increase in AOA results in an increase in lift. That's the top of the blue curve in the plot below.



              At low angles of attack (AOA) planes are naturally stable in roll. The downgoing wing sees a higher AOA which results in more lift, and a restoring force. The upgoing wings sees a lower AOA, and less lift, so it is stabilizing too.



              At a high AOA, though, you are operating on the backside of the wing lift diagram. In the picture below, this would be at and beyond 20 degrees AOA.



              enter image description here



              Now, the upgoing wing sees more lift, which leads to positively reinforcing going up. Same but opposite on the downgoing. It sees less lift.



              Also, the red line shows drag. That downgoing wing (on inside of the spin) sees a great increase in drag, which will lead to a yaw towards that wing, i.e., pro-spin.



              So to get in the situation where a roll/yaw movement is positively reinforcing, you need to be in stalled AOA. You might start with just one wing, you'll get to both.



              JMHO!



              EDIT



              Here’s a NASA video of a wing with tufts when it is both on the inside of the spin and outside. Stalled in both (but different airflow).











              share|improve this answer











              $endgroup$









              • 2




                $begingroup$
                I think this is a good answer. I've been reading up on spins. While I think that maybe only one wing will stall during the departure phase of the spin, by the time the spin is in the developed stage both wings will be stalled. I think the test question could have been better worded though.
                $endgroup$
                – DLH
                4 hours ago






              • 1




                $begingroup$
                @DLH I think this is a poor answer because it is wrong.
                $endgroup$
                – Peter Kämpf
                4 hours ago












              • $begingroup$
                @PeterKämpf: Oh man I wish you had answered sooner, I was persuaded.
                $endgroup$
                – DLH
                4 hours ago










              • $begingroup$
                In your answer, you ask, "What is stalled?" Good question. So have you defined what you are considering stalled to mean for the purpose of the answer? Some people will think of stalled to mean something like, "not generating enough lift to oppose the force of weight". The technical answer is exceeding the critical angle of attack.
                $endgroup$
                – Ryan Mortensen
                3 mins ago
















              4












              4








              4





              $begingroup$

              Yes, both are stalled.



              I guess a nit-pick is on "what is stalled"? I adopt that you are at or beyond the point that an increase in AOA results in an increase in lift. That's the top of the blue curve in the plot below.



              At low angles of attack (AOA) planes are naturally stable in roll. The downgoing wing sees a higher AOA which results in more lift, and a restoring force. The upgoing wings sees a lower AOA, and less lift, so it is stabilizing too.



              At a high AOA, though, you are operating on the backside of the wing lift diagram. In the picture below, this would be at and beyond 20 degrees AOA.



              enter image description here



              Now, the upgoing wing sees more lift, which leads to positively reinforcing going up. Same but opposite on the downgoing. It sees less lift.



              Also, the red line shows drag. That downgoing wing (on inside of the spin) sees a great increase in drag, which will lead to a yaw towards that wing, i.e., pro-spin.



              So to get in the situation where a roll/yaw movement is positively reinforcing, you need to be in stalled AOA. You might start with just one wing, you'll get to both.



              JMHO!



              EDIT



              Here’s a NASA video of a wing with tufts when it is both on the inside of the spin and outside. Stalled in both (but different airflow).











              share|improve this answer











              $endgroup$



              Yes, both are stalled.



              I guess a nit-pick is on "what is stalled"? I adopt that you are at or beyond the point that an increase in AOA results in an increase in lift. That's the top of the blue curve in the plot below.



              At low angles of attack (AOA) planes are naturally stable in roll. The downgoing wing sees a higher AOA which results in more lift, and a restoring force. The upgoing wings sees a lower AOA, and less lift, so it is stabilizing too.



              At a high AOA, though, you are operating on the backside of the wing lift diagram. In the picture below, this would be at and beyond 20 degrees AOA.



              enter image description here



              Now, the upgoing wing sees more lift, which leads to positively reinforcing going up. Same but opposite on the downgoing. It sees less lift.



              Also, the red line shows drag. That downgoing wing (on inside of the spin) sees a great increase in drag, which will lead to a yaw towards that wing, i.e., pro-spin.



              So to get in the situation where a roll/yaw movement is positively reinforcing, you need to be in stalled AOA. You might start with just one wing, you'll get to both.



              JMHO!



              EDIT



              Here’s a NASA video of a wing with tufts when it is both on the inside of the spin and outside. Stalled in both (but different airflow).




















              share|improve this answer














              share|improve this answer



              share|improve this answer








              edited 3 hours ago

























              answered 6 hours ago









              MikeYMikeY

              55516




              55516








              • 2




                $begingroup$
                I think this is a good answer. I've been reading up on spins. While I think that maybe only one wing will stall during the departure phase of the spin, by the time the spin is in the developed stage both wings will be stalled. I think the test question could have been better worded though.
                $endgroup$
                – DLH
                4 hours ago






              • 1




                $begingroup$
                @DLH I think this is a poor answer because it is wrong.
                $endgroup$
                – Peter Kämpf
                4 hours ago












              • $begingroup$
                @PeterKämpf: Oh man I wish you had answered sooner, I was persuaded.
                $endgroup$
                – DLH
                4 hours ago










              • $begingroup$
                In your answer, you ask, "What is stalled?" Good question. So have you defined what you are considering stalled to mean for the purpose of the answer? Some people will think of stalled to mean something like, "not generating enough lift to oppose the force of weight". The technical answer is exceeding the critical angle of attack.
                $endgroup$
                – Ryan Mortensen
                3 mins ago
















              • 2




                $begingroup$
                I think this is a good answer. I've been reading up on spins. While I think that maybe only one wing will stall during the departure phase of the spin, by the time the spin is in the developed stage both wings will be stalled. I think the test question could have been better worded though.
                $endgroup$
                – DLH
                4 hours ago






              • 1




                $begingroup$
                @DLH I think this is a poor answer because it is wrong.
                $endgroup$
                – Peter Kämpf
                4 hours ago












              • $begingroup$
                @PeterKämpf: Oh man I wish you had answered sooner, I was persuaded.
                $endgroup$
                – DLH
                4 hours ago










              • $begingroup$
                In your answer, you ask, "What is stalled?" Good question. So have you defined what you are considering stalled to mean for the purpose of the answer? Some people will think of stalled to mean something like, "not generating enough lift to oppose the force of weight". The technical answer is exceeding the critical angle of attack.
                $endgroup$
                – Ryan Mortensen
                3 mins ago










              2




              2




              $begingroup$
              I think this is a good answer. I've been reading up on spins. While I think that maybe only one wing will stall during the departure phase of the spin, by the time the spin is in the developed stage both wings will be stalled. I think the test question could have been better worded though.
              $endgroup$
              – DLH
              4 hours ago




              $begingroup$
              I think this is a good answer. I've been reading up on spins. While I think that maybe only one wing will stall during the departure phase of the spin, by the time the spin is in the developed stage both wings will be stalled. I think the test question could have been better worded though.
              $endgroup$
              – DLH
              4 hours ago




              1




              1




              $begingroup$
              @DLH I think this is a poor answer because it is wrong.
              $endgroup$
              – Peter Kämpf
              4 hours ago






              $begingroup$
              @DLH I think this is a poor answer because it is wrong.
              $endgroup$
              – Peter Kämpf
              4 hours ago














              $begingroup$
              @PeterKämpf: Oh man I wish you had answered sooner, I was persuaded.
              $endgroup$
              – DLH
              4 hours ago




              $begingroup$
              @PeterKämpf: Oh man I wish you had answered sooner, I was persuaded.
              $endgroup$
              – DLH
              4 hours ago












              $begingroup$
              In your answer, you ask, "What is stalled?" Good question. So have you defined what you are considering stalled to mean for the purpose of the answer? Some people will think of stalled to mean something like, "not generating enough lift to oppose the force of weight". The technical answer is exceeding the critical angle of attack.
              $endgroup$
              – Ryan Mortensen
              3 mins ago






              $begingroup$
              In your answer, you ask, "What is stalled?" Good question. So have you defined what you are considering stalled to mean for the purpose of the answer? Some people will think of stalled to mean something like, "not generating enough lift to oppose the force of weight". The technical answer is exceeding the critical angle of attack.
              $endgroup$
              – Ryan Mortensen
              3 mins ago













              2












              $begingroup$

              A spin is an autorotation that requires an asymmetric thrust force to sustain. This requires the wing span to be anchored at one end by drag, with the other end developing enough thrust to overcome the (rather weak) stabilizing force of the vertical fin and drive that end forward, rotating the plane. The AOA is highest at the inboard end and decreases as you move outboard due to the higher forward velocity. At some point along the span, the outer end is unstalled or only semi-stalled and is making at least some amount of lift/thrust.






              share|improve this answer









              $endgroup$


















                2












                $begingroup$

                A spin is an autorotation that requires an asymmetric thrust force to sustain. This requires the wing span to be anchored at one end by drag, with the other end developing enough thrust to overcome the (rather weak) stabilizing force of the vertical fin and drive that end forward, rotating the plane. The AOA is highest at the inboard end and decreases as you move outboard due to the higher forward velocity. At some point along the span, the outer end is unstalled or only semi-stalled and is making at least some amount of lift/thrust.






                share|improve this answer









                $endgroup$
















                  2












                  2








                  2





                  $begingroup$

                  A spin is an autorotation that requires an asymmetric thrust force to sustain. This requires the wing span to be anchored at one end by drag, with the other end developing enough thrust to overcome the (rather weak) stabilizing force of the vertical fin and drive that end forward, rotating the plane. The AOA is highest at the inboard end and decreases as you move outboard due to the higher forward velocity. At some point along the span, the outer end is unstalled or only semi-stalled and is making at least some amount of lift/thrust.






                  share|improve this answer









                  $endgroup$



                  A spin is an autorotation that requires an asymmetric thrust force to sustain. This requires the wing span to be anchored at one end by drag, with the other end developing enough thrust to overcome the (rather weak) stabilizing force of the vertical fin and drive that end forward, rotating the plane. The AOA is highest at the inboard end and decreases as you move outboard due to the higher forward velocity. At some point along the span, the outer end is unstalled or only semi-stalled and is making at least some amount of lift/thrust.







                  share|improve this answer












                  share|improve this answer



                  share|improve this answer










                  answered 4 hours ago









                  John KJohn K

                  24.4k13674




                  24.4k13674























                      0












                      $begingroup$

                      This "test" question may apply to a certain type of aircraft and spin procedure (Cessna 172) that has to be stalled straightforward (there for both wings stalled), followed by the "wrong" inputs (rudder into spin, ailerons away) to make it spin. The important concept is that differences in drag and lift between the 2 wings, whether one is stalled or not, keeps the plane in a self sustaining yaw/slip.



                      Important is the role of the V stab/rudder in maintaining or ending the spin. Looking at a simple cup shaped anomometer helps visualize the effects of pro-spin rudder into the spin and anti-spin rudder away. Stopping yaw with opposite rudder is key to breaking a spin, and controlling yaw is key to not entering one.



                      Also key is how uncoordinated aileron input, trying to roll away from a turn, can cause a spin.
                      (The "inside" slower wing is now compounded with the down aileron creating a higher AOA).
                      Although aileron roll effect can reverse in the stall AOA regime, rudder will not. But this also means that applying opposite ailerons in a spin can be explored! (Qualified instructor recommended).



                      But for the 172, just letting go of the yoke, power to idle, and opposite rudder would break the spin if CG was correct.



                      Every plane and situation is different (as seen by these answers), it is advisable to find out how your plane handles and how to control it, no matter what the "correct" test answer is.






                      share|improve this answer











                      $endgroup$


















                        0












                        $begingroup$

                        This "test" question may apply to a certain type of aircraft and spin procedure (Cessna 172) that has to be stalled straightforward (there for both wings stalled), followed by the "wrong" inputs (rudder into spin, ailerons away) to make it spin. The important concept is that differences in drag and lift between the 2 wings, whether one is stalled or not, keeps the plane in a self sustaining yaw/slip.



                        Important is the role of the V stab/rudder in maintaining or ending the spin. Looking at a simple cup shaped anomometer helps visualize the effects of pro-spin rudder into the spin and anti-spin rudder away. Stopping yaw with opposite rudder is key to breaking a spin, and controlling yaw is key to not entering one.



                        Also key is how uncoordinated aileron input, trying to roll away from a turn, can cause a spin.
                        (The "inside" slower wing is now compounded with the down aileron creating a higher AOA).
                        Although aileron roll effect can reverse in the stall AOA regime, rudder will not. But this also means that applying opposite ailerons in a spin can be explored! (Qualified instructor recommended).



                        But for the 172, just letting go of the yoke, power to idle, and opposite rudder would break the spin if CG was correct.



                        Every plane and situation is different (as seen by these answers), it is advisable to find out how your plane handles and how to control it, no matter what the "correct" test answer is.






                        share|improve this answer











                        $endgroup$
















                          0












                          0








                          0





                          $begingroup$

                          This "test" question may apply to a certain type of aircraft and spin procedure (Cessna 172) that has to be stalled straightforward (there for both wings stalled), followed by the "wrong" inputs (rudder into spin, ailerons away) to make it spin. The important concept is that differences in drag and lift between the 2 wings, whether one is stalled or not, keeps the plane in a self sustaining yaw/slip.



                          Important is the role of the V stab/rudder in maintaining or ending the spin. Looking at a simple cup shaped anomometer helps visualize the effects of pro-spin rudder into the spin and anti-spin rudder away. Stopping yaw with opposite rudder is key to breaking a spin, and controlling yaw is key to not entering one.



                          Also key is how uncoordinated aileron input, trying to roll away from a turn, can cause a spin.
                          (The "inside" slower wing is now compounded with the down aileron creating a higher AOA).
                          Although aileron roll effect can reverse in the stall AOA regime, rudder will not. But this also means that applying opposite ailerons in a spin can be explored! (Qualified instructor recommended).



                          But for the 172, just letting go of the yoke, power to idle, and opposite rudder would break the spin if CG was correct.



                          Every plane and situation is different (as seen by these answers), it is advisable to find out how your plane handles and how to control it, no matter what the "correct" test answer is.






                          share|improve this answer











                          $endgroup$



                          This "test" question may apply to a certain type of aircraft and spin procedure (Cessna 172) that has to be stalled straightforward (there for both wings stalled), followed by the "wrong" inputs (rudder into spin, ailerons away) to make it spin. The important concept is that differences in drag and lift between the 2 wings, whether one is stalled or not, keeps the plane in a self sustaining yaw/slip.



                          Important is the role of the V stab/rudder in maintaining or ending the spin. Looking at a simple cup shaped anomometer helps visualize the effects of pro-spin rudder into the spin and anti-spin rudder away. Stopping yaw with opposite rudder is key to breaking a spin, and controlling yaw is key to not entering one.



                          Also key is how uncoordinated aileron input, trying to roll away from a turn, can cause a spin.
                          (The "inside" slower wing is now compounded with the down aileron creating a higher AOA).
                          Although aileron roll effect can reverse in the stall AOA regime, rudder will not. But this also means that applying opposite ailerons in a spin can be explored! (Qualified instructor recommended).



                          But for the 172, just letting go of the yoke, power to idle, and opposite rudder would break the spin if CG was correct.



                          Every plane and situation is different (as seen by these answers), it is advisable to find out how your plane handles and how to control it, no matter what the "correct" test answer is.







                          share|improve this answer














                          share|improve this answer



                          share|improve this answer








                          edited 1 hour ago

























                          answered 2 hours ago









                          Robert DiGiovanniRobert DiGiovanni

                          2,6181316




                          2,6181316






























                              draft saved

                              draft discarded




















































                              Thanks for contributing an answer to Aviation Stack Exchange!


                              • Please be sure to answer the question. Provide details and share your research!

                              But avoid



                              • Asking for help, clarification, or responding to other answers.

                              • Making statements based on opinion; back them up with references or personal experience.


                              Use MathJax to format equations. MathJax reference.


                              To learn more, see our tips on writing great answers.




                              draft saved


                              draft discarded














                              StackExchange.ready(
                              function () {
                              StackExchange.openid.initPostLogin('.new-post-login', 'https%3a%2f%2faviation.stackexchange.com%2fquestions%2f62020%2fin-a-spin-are-both-wings-stalled%23new-answer', 'question_page');
                              }
                              );

                              Post as a guest















                              Required, but never shown





















































                              Required, but never shown














                              Required, but never shown












                              Required, but never shown







                              Required, but never shown

































                              Required, but never shown














                              Required, but never shown












                              Required, but never shown







                              Required, but never shown







                              Popular posts from this blog

                              Reichsarbeitsdienst

                              Statuo de Libereco

                              Tanganjiko