US2850251A

US2850251A - Roll compensator for guided missiles

Info

Publication number: US2850251A
Application number: US421991A
Authority: US
Inventors: Wilbur A Joerndt
Original assignee: Individual
Current assignee: Individual
Priority date: 1954-04-08
Filing date: 1954-04-08
Publication date: 1958-09-02
Anticipated expiration: 1975-09-02
Also published as: US2859315A

Description

p 2, 1958 w. A. JOERNDT 2,850,251

ROLL COMPENSATOR FOR GUIDED mssmas Filed April 8, 1954 2 Sheets-Sheetl A l FIG. I.

' I /3 a T 1 INSULATION T0 HORIZ. FIN SERVO(OUTPUT) T0 VERT. FIN SERVO (OUTPUT) TO VERT. FIN SERVO (OUTPUUi 46 TP T) Q /3MWRNEYS 6;. INVENTOR FIG. V W/L BUR A. JOERNDT I Sept. 2, 1958 w. A. JOERNDT 2,850,251

ROLL COMPENSATOR FOR GUIDED MISSILES Q5 i E N i WNW! A. WW

aten t Patented Sept. 2, 1958 2,850,251 RoLL COMPENSATOR FOR GUIDED MISSILES WilburA. Joerndt, Albuquerque, N. Mex., assignor to the United States of America as represented by the Secretary of the Navy Application April 8, 1954, Serial No. 421,991

Claims. (Cl. 244-14) This invention relates in general to roll compensation systems for guided. missiles, and in particular it relates to apparatus for generating roll compensated guide beam error signals when a guided missile is rolling.

It is one of the objects of this invention to provide apparatus for modifying target misalignment signals of a guided missile, and for adjusting the position of the fins to correct for guide beam misalignment to roll compensate the missile.

Another object of the invention is to provide apparatus for applying guide beam error signals modified to compensate for roll of a missile to the servo-stabilizing system of a guided missile in order to roll compensate the missile.

Still another object of the invention is to provide apparatus for determining and applying guide beam error signals modified to roll compensate a missile, which is compact, easy to manufacture and install in the missile,

and eflicient and reliable in operation.

Other objects and many of the attendant advantages of thisinvention will be readily appreciated as the same becomes better understood by reference to the following tion;

Fig. 4 is a schematic of the circuitry for the apparatus of Figs. 2 and 3;

Fig. 5 is a cross section along line 55 of Fig. 2; and Fig. 6 is a schematic illustrating the position of the missile in a guidance beam of electromagnetic energy.

In accordance with the invention, apparatus is provided for determining and applying guide beam error signals compensated for roll movements of a guided missile to the servo-stabilizing system'thereof. This apparatus comprises means for producing a resistance path variation responsive to roll movements of the missile. These means comprise a plane resistance surface which is immovable relative to the missile, with one or more pairs of contacts bearing on the resistance surface and being rotatable relative to the resistance surface as by a-free gyroscope stabilizing the contacts against roll. Any shifting of the surface relative to the contacts produces a change in the path of current flow in the surface. The contacts pick up parts of the voltage drops due to the guide beam error signals. These modified error signals are fed to amplifying means where they are amplified and are used to control a hydraulic servo system. The hydraulic servo system, in turn, is utilized to adjust the position of the missile fins to return the missile to the guide beam.

Referring now to Fig. 1 of the drawings, there is shown an aerial missile 10 of either the rocket or ramjet type, which has a plurality of fixed wings 12 for flying the missile and a plurality of fins 14 for steering the missile while it is in aerial flight along a trajectory.

As illustrated in Fig. 6, a standard radar transmitter 11, located at a remote point in space and having a pulse repetition rate frequency modulated in synchronism with its scan rate, is utilized to project a guidance beam 8 of electromagnetic energy to guide the missile 10.

When the missile 10 is not travelling centrally along the guide beam, input error signals are picked up by an antenna 13 mounted on one of the fins 14 of the missile 10 and are fed to suitable conventional means, such as a guide beam error measuring device 17, and

thence to a guide beam error signal modifying apparatus 1 20. A free gyroscope 18, is mechanically connected to a shaft 28 (Fig. 2) in such a way that when rolling of the missile occurs, this shaft will be stabilized against turning by the gyroscope 18. Apparatus 20 modifies the up-down misalignment signal, as well as the right-left misalignment signal of the missile 10 responsive to roll. These modified guide beam error signals are then fed to a suitable amplifying means 22, and are used to control port for the shaft 28. This bearing also serves as a cover a or closure for one end of the casing 26.

Shaft 28, as illustrated in Fig. 3, carries a cylinder 32, which is likewise made of a suitable insulating material, and upon which are located four (4)

slip rings

34, 36, 38, and 40. Upon the slip rings rest the ends of four (4)

conductors

42, 44, 46, and 48, which are made of relatively fine wire and which are arranged to bear resiliently on the

slip rings

34, 36, 38, and 40, respectively.

Slip rings

34, 36, 38, and 40, in turn, are connected to

contacts

50, 52, 54, and 56, by means of

leads

58, 60, 62, and 64, as shown by dotted lines.

Contacts

50, 52, 54, and 56 may be of any desired shape. However, they are shown here as metal spheres'which are carried in corresponding apertures 65, 66, 68, and 70, in an insulating disk 72. Insulating disk 72 is secured to the cylinder 32 so as to rotate therewith when the latter r0- tates with shaft 28.

It is to be understood, furthermore, that while two types of contact members are shown, namely, the resilient type of contacts for the

conductors

42, 44, 46, and 48, which engage the

slip rings

34, 36, 38, and 40, respectively, and the metal spherical type of

contacts

50, 52, 54, and 56, the springs and the spheres may all be of a single type. Regardless of the type of contacts associated with the disk 72, each such contact will bear resiliently against the adjacent surface of a stationary disk 74.

The stationary disk 74, which is mounted in the enlarged portion of the casing 26, has a coating of highresistance material on the face 75 thereof adjacent disk 72. For example, this material can comprise carbon tween opposite sides.

i 3 carried or placed on any suitable insulating material, on the disk 74.

Electrical contact is made with this coating by means of four (4)

metal terminal members

73, 86, 82, and 84, such as illustrated in Fig. 4. These metal contact members are arcuate, and each is equivalent in length to 45. These

contact members

78, 80, 82, and 84, are arranged symmetrically around the disk 74.

Conductors

86, 88, 90, and 92 connect to the

terminal contacts

78, 80, 82, and 84, respectively, with opposite ones, for example, 86 and 9t), and 88 and 92, constituting paired circuit conductors for receiving the respective misalignment signals from the error signal guide beam apparatus 17, that is, the up-down and right-left misalignment signals due to errors in direction of travel of the missile 1%.

An electrical field is set up in the plane of the disk 74, the value of which at any point is the vector sum of the electrical fields due to the misignment signals applied at the pairs of

terminals

78, 82, and 8t), 84. Assuming, for example, the application of instantaneously equal misalignment signals at

contact terminals

78, 82, and 80, 84, the field vector in the neighborhood of the central region of the disk 74, upon which the contacts 59, S2, 54, and 56 bear, would bisect the angle between the component fields. If it is assumed that the electrical field is uniform over the central region bounded by the contacts 50, S2, 54, and 56, then the potential difference between

opposite contacts

50 and 54, or 52 and 56 is given by the projection of the resultant vector upon the line joining such pairs of contacts multiplied by their distance apart.

Let F,,+F be the component fields in the disk 74 due to the separate misalignment signals, r the distance of the contacts 5%), 52, .54, and 56 from the axis of rotation of the shaft 28, and 6 the angle between the line joining

opposite contacts

52, 56 or 50, 54, and the y and x axes of the disk 74.

Then the resultant field vector Ewan.

making an angle with the y axis such that If the applied voltage varies, the angle varies according to the foregoing relationship. The voltage developed between a pair of contacts, such as '50 and 54, will then be :given by the expression and the voltage developed between

contacts

52 and 56 will be given by the expression It will be seen that if 6 is also the angle of relief the missile 10, and the voltages or potential V or V are now applied to the appropriate fin servo mechanism, such as the hydraulic servo mechanism 24, modification of the original error signals to take care of roll of the missile can be achieved.

In accordance with the principles of vector combination, the two signals, which are at right angles to one another for the system indicated in Fig. 4, pass through the apparatus without mutual interference. These two signals may then be conveyed simultaneously to the amplifier arrangement 22, where they are amplified, and to the hydraulic servo stabilizing system 24.

The operation of the invention will now be explained. After the aerial missile 10 has been launched by suitable launching means (not shown) and is in flight along its trajectory, it is assumed that the missile is subjected to rolling movements. The casing 26, of the guide beam error signal modifying apparatus, is stationary with respect to the missile 10. However, means such as the free gyroscope 18, is connected to the shaft 28 in such '4 a manner that, when rolling of the missile occurs, this shaft 28 will be stabilized against roll by the gyroscope 18.

If now the up-down misalignment signal is applied to the

terminals

86 and 90, and the right-left misalignment signal to the

terminals

88 and 92, then currents will flow in the resistance surface of the disk 74 between the

respective terminals

78 and 82, or 80 and 84, and of proper values to represent the guide signal errors existing at the moment. The

contacts

50, 52, 54, and 56, which bear on the resistance surface of disk 74, will thus pick up proportional parts of the respective voltage drops produced by the guide signal error currents. For example, if constant D. C. voltages are maintained across

terminals

86 and 90, upon rotation the

contacts

42 and 46 will derive a simple harmonic voltage, that is, a sine wave voltage, therefrom. Likewise, if constant direct current voltages are maintained across

terminals

88 and 92, upon rotation of shaft 28 the

contacts

44 and 48 will derive a simple harmonic voltage, that is, a sine wave voltage, therefrom. These voltages are then fed simultaneously to the amplifier 22 and to the hydraulic servo system 24 and the latter is used to control the fins 14 of the missile 10 through suitable mechanical linkages, such as 15 and 16.

As previously stated, either spheres or springs may serve as the actual contact elements. However, it has been found that it requires more torque to operate the roll error signal apparatus 20 with ball contacts than when thin wires are used. Therefore, it is preferred to use the thin wires, since this imposes less load on the gyroscope 18, and, consequently, does not cause serious precess'ional movements of the gyroscope.

It is also to be pointed out that instead of having the contact rings 34, 36, 38, and 40 rotate, and the springs of

contacts

42, 44, 46, and 48 remain stationary, these elements may be interchanged, so that the cylinder 32 will carry wire springs and the slip rings 34, 36, 38, and 40 will then be mounted in the stationary casing 26. This form may require more torque to operate it, inasmuch as the contacts will then be more remote from the axis of the shaft 28.

Obviously many modifications and variations of the present invention are possible in the light of the above teachings. It is, therefore, to be understood that within the scope of the appended claims the invention may be practiced otherwise than as specifically described.

What is claimed is:

1. In combination, an aerial missile, means for generating a beam of electromagnetic energy for guiding said missile, means in said missile for generating an electric signal representative of guide beam error, apparatus for modifying said guide beam error signal responsive to rolling movement of said missile, said apparatus including a casing having a resistor therein, said resistor having spaced terminals and a substantially fiat surface between said terminals, a pair of spaced contacts bearing on said surface, and a shaft mounted to rotate in said casing, said resistor and pair of contacts being carried by said casing and shaft in such a manner that relative rotation of said shaft and casing will shift said contacts angu'larly over said surface, thereby producing a variation in the resistance path between said contacts and terminals which -is a function of said guide beam error signal.

2. In combination, an aerial missile, means for generating a beam of electromagnetic energy for guiding said missile, means in said missile for generating electric signals representative of up-down and right Ieft guide beam error, apparatus for modifying said guide beam error signals responsive to rolling movement of said missile, said apparatus including a casing having a resistor therein, said resistor having up-down signal terminals and right-left signal terminals and a substantially flat surface therebetween, two pairs of spaced contacts bearing on said surface, with the line connecting said contacts of one pair of spaced contacts being substantially at right angles to the line joining said contacts of said other pair of spaced contacts, a shaft mounted to rotate in said casing, said resistor and two pairs of contacts being carried by said casing and shaft in such a manner that relative rotation of said shaft and casing will shift said two pairs of contacts angularly over said surface, thereby providing variations in the resistance paths between said contacts and terminals which are a function of said error signals.

3. In combination, an aerial missile having movable fins, means for generating a beam of electromagnetic energy for guiding said missile, means in said missile for generating electric signals representative of up-down and right-left guide beam error and having a plurality of fins for up-down and right-left steering of said missile, apparatus for modifying said guide beam error signals responsive to roll movements of said missile, including means having up-down and right-left beam error signal contacts and a resistance surface therebetween, a free gyroscope, at least one pair of contacts bearing on said resistance surface and being stabilized against roll by said gyroscope, means for picking said modified beam error signals from said resistance surface, means for amplifying said modified signals, and means for utilizing said signals to control said fins of said aerial missile for steering it into alignment with the guide beam.

4. In combination, an aerial missile having movable fins for steering said missile, means for generating a beam of electromagnetic energy for guiding said missile, means in said missile for generating electric signals representative of guide beam error, apparatus for modifying said beam error signal responsive to roll movement of said missile, said apparatus including a first element carried by said missile to partake of said roll movement of said missile, a second element coacting with said first element, means for varying the relative positions of said elements in response to rolling movement of said missile, resistancevarying means for modifying said beam error signals responsive to the relative motion of said elements, means for picking said modified beam error signals from said resistance-varying means, means for amplifying said modified signals, and means for utilizing said amplified signals to control said movable fins for steering said missile into alignment with said guide beam.

In combination, an aerial missile having a plurality of movable fins for steering said missile, means for generating a beam of electromagnetic energy for guiding said missile, means in said missile for generating an electric signal representative of guide beam error, apparatus for modifying said guide beam error signal responsive to roll movement of said missile, said apparatus including a casing, said casing having a resistor therein, said resistor having spaced terminals for receiving the beam error signal and a substantially flat resistor surface therebetween, a free gyroscope, at least one pair of spaced contacts bearing on said surface and being stabilized against rolling by said gyroscope, a shaft mounted to rotate in said casing, said resistor and said pair of contacts being carried by said casing and shaft in such a manner that relative rotation of said shaft and easing will shift said contacts angularly over said surface, said contacts constituting means for picking a modified beam error signal from said resistance surface, means for amplifying said modified signal, and means for utilizing said amplified signal to control said fins of said missile in order to steer the latter into alignment with said guide beam.

References Cited in the file of this patent UNITED STATES PATENTS 2,137,812 Sche1lenger Nov. 22, 1938 2,141,907 Hathorn Dec. 27, 1938 2,406,293 Hammond Aug. 20, 1946 2,616,640 Bedford Nov. 4, 1952 2,769,601 Hagopian Nov. 6, 1956 2,775,421 Markusen Dec. 25, 1956 2,784,924 Gille Mar. 12, 1957