DE2759499C2 - Accelerometer - Google Patents

Description

- That the first slot (112) of a pair of slots extends perpendicularly from one side of the belt (86) behind the longitudinal axis of the belt (86) and the second slot (114) perpendicular to the other side of the belt (86) behind the longitudinal axis of the band (86) extends

The invention relates to an accelerometer,

with a housing, a pendulum, a shaft mounted transversely to the longitudinal axis of the pendulum, which is in an im Housing attached Haltcrahmen is rotatably mounted in two shaft bearings. Such an accelerometer shows US-PS 38 97 690th The seismic mass is about Shaft journal mounted on a bearing in a housing, the bearing being carried out via two self-supporting leaf springs. An elastic material is also provided between the leaf springs and the journals.

This arrangement makes it difficult to pinpoint one accurately to generate adjustable pressure on the bearings of the shaft so that on the one hand a precise alignment of the shaft (and thus the pendulum) is guaranteed and, on the other hand, the rotational friction is reduced to a minimum

30 turns. The US-PS 33 39 419 relates to an accelerometer with a differential capacitor tap. But this accelerometer has a clamped in place Pendulum-like mass on which an electromagnetic Attacks Rückieilsystem, wherein the mass is stored on one side. Adjustment of this storage is not possible.

The US-PS 39 48 107 relates to a speed converter, in which also leaf springs for storage be used.

The US-PS 36 18 401 relates to an accelerometer with a capacitive tap between two condenser plates in which the pendulum engages. The shaft bearing is not dealt with here With the increasing use of accelerometers in small aircraft and guided missiles or projectile navigation systems of light weight, the Reducing the size and weight of accelerometers is very important. Additionally who the accelerometer often under conditions it turns relatively strong shocks, vibrations and subject to sudden changes in temperature, all of which affect the accuracy of the device can. Hence, it is important to have the number of parts as well Total weight and dimensions of the system reduce so that the effects of shock and temperature can be minimized.

Conventional accelerometers, because of the relatively large capacitors, require rather large

ße housing, in particular to accommodate the associated electronics or a separate housing for these electronics. As conventional accelerometers usually consist of a force sensor and a separate one Electronics exist, they require increased labor

6 ^P > and installation effort for the numerous units together with additional electrical connections, which represent possible failure conditions, especially in unfavorable surroundings.

The invention has made it its business to provide a To improve accelerometers of the type mentioned above that with a small space requirement and reduced production and installation of a measuring device that works precisely even under difficult conditions, such as shock, vibration and temperature changes, and precise adjustment of the shaft bearings should be possible.

According to the invention, this object is achieved by the characterizing features of claim 1.

The subclaims characterize further expedient developments.

The inventive design of an accelerometer can align the shaft can be significantly simplified, at the same time the bearing friction is significantly reduced. It will This eliminates sources of error which can have a very unfavorable effect on the measuring device, especially in the event of a misalignment. In addition, the embodiment according to the invention a small space requirement, low wear and thus a long service life of the device achieved.

In the drawings, exemplary embodiments of the accelerometer according to the invention are shown

F i g. 1 shows a longitudinal section through the entire accelerometer,

F i g. 2 is a plan view of part of the accelerometer of FIG. 1 with a shaft bearing;

F i g. 3 is a top plan view of a portion of the accelerometer of FIG. 1 with a different shaft bearing,

Fig. 4 a band for the shaft bearing according to Fi,?. 2 Or 3,

F i g. 5 another band for the shaft bearing according to Fig.2undJ.

F i g. 6 another band for the shaft bearing according to Fig. 2 or 3,

7 shows a pendulum for the accelerometer according to Fig. 1,

F i g. 8 another pendulum for the accelerometer according to FIG. 1.

As shown in FIG. 1, a one-piece housing 12 encloses the mechanical and electronic Accelerometer parts. The left end 14 of the housing 12 is closed, while the right Side is open. A one-piece Haltcrahmcn 16 with its parts 16 / 4,16S, 16C etc. forms a rigid support for the various components of the accelerometer. The holding frame 16 extends from the left End 14 of the housing to the open end and substantially fills the lower half of the housing 12, such as this by the reference numerals 16/4, 166, 16C and 16Ο is indicated. Above the part 16Λ of the holding frame 16, two substantially rectangular capacitor plates 18 and 20 are provided. The lower capacitor plate 20 is with a binder, such as. B. Epoxy resin, on part 16/4 of the holding frame 16 over a spacer 22 attached. The upper capacitor plate 18 is in turn spaced from the lower plate 20 by means of a plurality of posts 23 and 24 which are attached to each corner of the capacitor plates are attached.

Furthermore, FIG. 1 the pendulum 26. which acts as a seismic or sample mass and responds to acceleration forces that are directed upwards or downwards. A portion 28 of the pendulum 26 is in the form of a flat plate and is parallel between the capacitor plates 18 and 20 introduced. In a preferred embodiment

10 rungsbeispicl of the invention have the sheet 28 and the Capacitor plates 18 and 20 have a width of approximately 0.64 cm and a length of 0.51 cm, resulting in capacitance between the sheet 28 and the capacitor plates 18 and 20 of approximately 2 to 4 pF leads. If so the plate is 28 in the middle between the capacitor plates 18 and 20 is, the capacitance between the capacitor plates is about 2 to 4 pF. At the other end of the pendulum 26 is a shaft 30 to the bottom 32 of the pendulum 28 by means of a binder, such as. B. epoxy resin connected. The shaft 30 supports the pendulum 26 and allows its limited rotation or pivoting with acceleration forces acting perpendicular to the surface of the plate 28. The shaft 30 is or is itself dutch Tapes (Fig.2 and 3) stored for simplification the illustration in Fig. 1 are omitted. Farther a rotating coil 36 is provided on the underside 32 of the pendulum 26 between the plate 28 and the shaft 30. The moving coil 36 is within a bobbin 38, which is preferably made of lightweight material. such as B. aluminum. One Free-standing coil can also be provided without the coil body.

A permanent magnet 40 is with the holding frame 16Λ connected, and a pole piece 41 is similarly connected to the top of the permanent magnet 40. The magnetic flux generated by the permanent magnet 40 interacts with the current flowing in the moving coil 36 and causes the pendulum to rotate 26 around the shaft 30. The one-tier holding frame 16.4 generates, in addition to the storage of the permanent magnet 40, a magnetic circuit for the magnetic flux formed by the permanent magnet 40.

On raised portions 16F and 16G of the one-piece support frame 16 is a rectangular circuit board 42 attached, which is preferably made of a non-conductive substrate such. B. alumina, consists of the left Side of the circuit board 42 is on an upper projection IeF of the holding frame 16, and the right Side of the sound board 42 is similarly on an upward portion 16C of the support frame 16. An integrated circuit 44 is through a Metal cover 46 on the top of the formwork panel 42 is enclosed. Furthermore, 42 cine I lybrid circuit together with a are on the shuttering panel Number of electronic individual components provided, such as B. resistors and capacitors what by a component 48 is indicated

The right part 16C of the holding frame 16 has one Ringzylindcr- Tcil 16D and 16 £ of the in the inner radius of the housing 12 is fitted. After assembly, the parts 16O and 16 £ dt? Holding frame Hermetically welded along the circumference of the housing 12, as indicated at points 50 and 52. to form a gas-tight seal. The open end of the housing 12 also closes a head piece 54 an annular recess 56 which is contained in the annular part 16D and 16 £ of the support frame 16 The head piece 54 is also hermetically welded along the inner circumference of the holding frame parts 16D and 16 £, as indicated at points 58 and 60, to form a gas-tight seal. For some applications, the housing 12 need not be hermetically sealed, so that the head piece on the housing can be attached by epoxy resin or other materials that are not gas-tight. A plurality of connecting pins extend through the head piece 54 62 *. 620.62C and 62D. with a gas-tight seal

is achieved with the head piece 54 through glass 64 and 66. The head piece 54 also has an opening 68, the for evacuating air from the housing 12 and to the Filling with inert gas after assembly can be used. This opening 68 can be different Way to be completed, including welding a component such. B. a ball 70. with the outer end of the opening 68 in an annular Recess 71 of the head piece 54, as shown in FIG. 1 is shown. Several leads 72 are with the pins 62A 62ß, 62C and 62D and the shuttering panel 42 connected.

In order to electrically connect the moving coil 38 to the circuit board, two spring wire lines, one of which is a line 74 in FIG. 1, connected to pendulum 26 at shaft 30. The wire 74 is attached to a pin 76, which in turn passes through a holding member 78 made of insulating material and then through a hole or opening 80 in the formwork panel 42 extends. The second spring wire and a second pin 77 (see FIG. 2) are on the pendulum in a similar manner 26 and the circuit board 42 to form a second connection for the moving coil 38. The pen 76 is then connected to circuit board 42 by lead wire 82. Through pins 76 and 77, the extend through the openings 80 in the formwork panel 42 (see FIG. 1), the assembly of the accelerometer facilitated as the plate 42 is positioned directly on the support frame portions 16F and 16C and can be connected to a pin 76 immediately. Through the spring wires 74 and 75 for the connection the pendulum 26 can be finely balanced by applying a small torque to the shaft 30, whereby small mechanical imbalances in the pendulum 26 are compensated. The torque acting on the shaft 30 can be done either by bending the spring wires 74 and 75 or by positioning the pins 76 and 77 can be set. The connection by means of the pins 76 and 77 and the opening 80 allows various thermal expansions of the support frame 16 and the circuit board 42 without disturbing the pin 76 and thus the Tension or adjustment of spring wire 74.

The bearing for the shaft 30 is shown in FIG. 2, which is a top plan view of a portion of the accelerometer 10 of FIG. 1 without the formwork panel 42 shows two straps 84 and 86 are fastened to projections 16H, 16 /, 16 / and 16AC of the one-piece retaining frame with fastening screws 88, 90, 92 and 94. Two bearings 96 and 98 are attached to the bands 84 and 86 and receive stone pins 100 and 102 provided at each end of the shaft 30. The bearings 96 and 98 support the shaft 30. so that the pendulum 26 can rotate about the shaft 30 while the movement of the shaft 30 is unfree in any other direction. so that plate 28 can move up and down between capacitor plates 18 and 20 (FIG. 1). With an instrument of high accuracy it is very important to reduce the rotational friction as much as possible, while at the same time the pendulum 28 is rigidly mounted so that lateral movement of the pendulum to the holding frame is excluded as far as possible. Therefore, for precise calibration and good operating properties, the optimal pressure must act on the stone pegs 100 and 102 via the bearings, so that the rotational friction is reduced as much as possible, while at the same time the lateral bearing has as high a value as possible. For this purpose, the accelerometer of FIG. 1 is provided with two adjusting screws 104 and. The set screws 104 and 106 are supported by integral projections 16L and 16M of the support frame 16. The holding frame part 16L is shown in FIG. 2 to show the position of the set screw 104. By tightening the set screws 104 and 106 on the bands 84 and 86, the appropriate pressure can be applied against the bands 84 and 86 resulting in optimal pressure on the shaft 30 through the bearings% and 98.

Another bearing for shaft 30 of FIG. 1 is in F i g. 3 shown. The holding frame 16 has a part

ίο 16Λ / who holds and stores the bearing%. The other Bearing 98 rests on belt 86 (FIG. 2), but no set screw 106 is provided. The setting the pressure on the shaft 30 takes place in FIG. 3 by means of a spring ring or spring clip 108. The at An C

tightening the fastening screw 94 is compressed. By setting the setting -. screw 94, the pressure on the shaft 30 can be effectively adjusted. Of course, the devices of FIG. 2 and 3 are used together; in that, for example, the adjusting screw 106 of FIG. 2 is used with the fixed bearing 96, which is attached directly to the holding frame 16Λ / is attached, as shown in Fig.3.
An important factor when setting the pressure on

2S the shaft 30 (Figs. 2 and 3) is the exact amount of flexion by the bands 84 and 86 for a given Pressure achieved by adjusting screws 104 and 106. To allow a greater bend in the ligaments for To achieve a given pressure, it is advantageous to provide slits in the bands. In Fig. 4 has z. B. tape 86 of FIG. 2 and 3 two U-shaped slots 112 and 114. The U-shaped slots 112 and 114 are located on each side of a bearing 116. It should be noted that the bearings in the F i g. 2.3 and 4 a conical,

M have inner surface 118 for receiving the tapering '' stone pegs 100 and 102 of the shaft 30 (Figs. 2 and 3). In addition, the tape in FIG. 4 holes 120 and I 122 in each end to accept mounting screws 94 & id 96. Other types of slots are found in the tapes of FIG. 5 and 6 shown in FIG. 5, there are between slots 124, 126 and 128, 130 on each side of the bearing 116, each slot being substantially perpendicular to the longitudinal axis of the belt 86 and extending from the side to a point past the center of the belt i g. 6-6, there are rectangular slots 132 and 134 on each side of the bearing 116 in the belt 86.

The bands of Figures 4, 5 and 6 show others as well Means for joining one end of the strap 86

M with the holding frame 16Λ / FIG. 3 without the separate spring ring 108 (FIG. 3). In Fig. 4, the end of the band is provided with a hole 120 with a cup-shaped part 136 which has a plurality of radial slots 138. In Figure 5, the band 86 with two leaf springs 140,.,

ss and 142 on each side of the mounting hole 120 provided. The belt 86 of FIG. 6 has two protrusions 144 and 146, which are bent by approx. 180 ° to make a spring \ form. The spring arrangement 136 or 142 or ' 146 against the frame together with the fastening iv

Mounting screw 94 in FIG. 3 can be the pressure on the white; ' Ic 30 without separate parts, such as. B. the spring ring 108 can be adjusted. i \

To the operating characteristics of the acceleration * -? mcssers 10 of FIG. To improve, the pendulum 26 must be light and rigid. Preferably the pendulum consists of '; 26 made of a relatively light metal, such as. B. AluminKv to. In addition, the pendulum 26 along its longitudinal _; nchsc to be stiffened. Two options for di4;>

Longitudinal strength of the pendulum 26 are shown in FIGS. 7 and 8 shown. In Fig. 7, the pendulum 26 consists of the flat plate 28 and a rod 148. On the rod 148 of the Pendulum 26 is attached to the bobbin 38, which contains the third coil 36 in FIG. 7 is the rod 134 by means of FIG two raised edges ISO and 152 along each side of the rod 148 stiffened longitudinally. In Fig. 8 is the rod 148 by means of a triangular sieve 154 made of the material of Rod 148 stiffened By strengthening the rod 148 of the pendulum 26 (Figs. 7 and 8) a light, but longitudinal to reinforced pendulum for the accelerometer 10 of FIG. 1 are made possible. Preferably the The main influence of the mass of the pendulum 26 is concentrated over the moving coil 36, while the mass of the other Parts of the pendulum 26, such as. B. the plate 28 and the is Rod 148, is as small as possible.

For this purpose 3 sheets of drawings

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Claims (9)

Patent claims: 1. Accelerometer, with a housing, a pendulum, one transverse to the longitudinal axis of the pendulum attached shaft, which is rotatably mounted in a holding frame mounted in the housing in two shaft bearings, characterized by - two spaced parallel capacitor plates (18, 20) which are fastened in the housing (12), - A sheet (28) fastened to one end of the pendulum (26) and spaced apart substantially in parallel between the capacitor plates (18, 20) intervenes, and - An adjusting device for the shaft bearings (96, 98) for adjusting the pressure of the bearings the shaft (30) consisting of a first flexible band (86) attached at both ends is attached to the retaining frame (16). 2. Accelerometer according to claim 1, characterized in that - That one of the bearings is attached directly to the holding frame (16) 3. Accelerometer according to claim 1, characterized in that - That each end of the shaft (30) has a stone journal 4. Accelerometer according to claim 1, characterized in that - That the first band (86) has a spring element at one end opposite the holding frame (16) having 5. Accelerometer according to claim 4, characterized in that - That the spring element is integral with one end of the first band (86). 6. Accelerometer according to claim 1, characterized in that ■ - that the adjusting device has a screw part (16L, 16Ai) on the holding frame (16) and an adjusting screw (104, 106), which with the Screw part is screwed, with one end of the adjusting screw (104,106) on the straps (84,86) is applied 7. Accelerometer according to claim 1, characterized in that - That the first band (86) has at least one slot (112,114) 8. Accelerometer according to claim 7, characterized in that - That the slot (112,114) is U-shaped. 9. Accelerometer according to claim 7, there marked by