DE563007C - Compressor with eccentric swinging movement - Google Patents

Description

Consisting of a drive part, a working part and one or more housing parts Compressor with an eccentric oscillating movement, in which the compression by the centrifugal effect of the drive system by means of transmission Centrifugal forces driven Arfoeitteils takes place, are known. These known embodiments have the disadvantage that the gear could not be balanced, the machine restless, intermittently and with beating Noise worked. The purpose of the invention is therefore through appropriate training to compensate for the speed of the compressor; and consists in that the centers of impact of the forces which, as the result of the, exerted on each part by the other parts Forces result, coincide for each individual part at a point and that the compressor is suspended in such a way that the The centers of the impact remain almost immobile. The subject of the invention is based on three embodiments shown schematically in the drawing.

Fig. Ι shows a compressor in the machine housing arranged drive motor, whose displacer as a result of the centrifugal effect of the eccentric oscillating Machine housing performs the compression. ' Figure 2 is a cross-section along the line H-II of Fig. I. -

In Fig. 3, a compressor is shown which in contrast to FIG. 1 from an outside of the machine housing 'located engine is driven. '■ ".. ·' '

Fig. 4 shows a compressor, .dessen arrival ■ 'tergehäuses drive motor does not follow the vibration of the Earn. ¹

Fig. 5 shows a particular type of suspension of the eccentric oscillating. Housing.

FIG. 6 provides the plan of FIG. 5 at raised upper cone plate.

Fig. 7 shows the housing part of the compressor according to Fig. 1,

Fig. 8 the corresponding drive part and 4-5. in the end

9 shows the associated working part.

Has an external effect on a mass body Force at any point of application, the body becomes a rotation around a certain one Execute the point, which is called the center of the impact, and its position the three main moments of inertia of the mass body can be determined, assuming that they are known. If this mass body becomes in the "joint center point rotatable in all directions on-T-hung, thus a physical pendulum arises, on which the action of this external force no reaction forces whatsoever on the suspension point exercises. The absolute magnitude of this external force is referred to in the following as the disturbance force be designated, no: one,

fluß on the position of the center of impact, but all at the absolute magnitude of the speed the movement it creates; "" "

For special body shapes that have an axis of symmetry, two of whose main moments of inertia are consequently the same, disturbance forces from different directions can have a common center of impact, provided that these forces lie in a plane perpendicular to the axis of symmetry of the body and the straight extension of which is the point of penetration from the Contains axis of symmetry of the body with the vertical plane. The center of impact for these forces is then in the axis of symmetry, which thus becomes the center of gravity of the body when suspended in the center of the impact. Likewise, the center of impact falls in systems of parallel forces whose Re- -. sultierende vertical in the same axis of symmetry, is the individual forces containing forces plane and the straight extension of the individual parallel forces ⁴ S as well as of their resultant, the symmetry axis of the body _S intersects together in the power level with the push center of the individual forces. Small deviations from these forces have only an insignificant influence on the position of the individual impact centers, so that a point in the middle position of the individual impact centers still represents a practically calm and shock-free suspension point. In the compressors according to FIGS. 1 and 2, the housing part consists of the machine housing 1 and the compressor housing 3, the drive part consists of the rotor 12 of the motor 2 and the weights 15 and 16, and finally the 4 »working part is formed by the displacer 24. The machine housing 1 is gimbaled to the fixed supports 5 at point 4. The two supports 9, which are rigidly connected to the cardan ring 8, are suspended from the two fixed hangers 6 by means of resiliently flexible straps 7. In the direction perpendicular to the plane of FIG. 2, through the point 4, the machine housing ι is in a corresponding manner by elastic bands 7 ° (Fig. 2), soft on the one hand with the carriers ψ of the ring 8 and on the other hand with the carriers 6 ^a of the housing ι are connected, * at. the ring 8 is suspended in such a way that the axis of bending of the flexible strips J ^a passes through point 4 again. - "■ ___"

With the housing 1 is the. fixed pole ring 10 of the motor 2 rigidly connected, .. while the shaft 11 with the rotor 12 is mounted in the bearings 13 and 14 located in the machine housing 1. On the motor shaft ir, the rotating masses 15 and 16, which are also referred to below as interference masses, are keyed offset from one another ^{by i8o p.} The housing 3 of the compressor contains in a cylindrical bore 18 the displacer 24, which leaves a sickle-shaped working space free in the cylindrical bore 18 and is provided with centrifugal masses A and B.

The compressor works as follows:

Due to the eccentrically rotating disturbance masses 15, 16 wedged on the shaft 11, a couple of forces 21, 22 act on the machine housing 1. As a result of these forces, the machine housing with its center of gravity 26, which forms the angle α with the common center of gravity 25 of the entire system , perform an eccentric swinging movement around point 4 so that the common center of gravity 25 remains immobile. As a result of this movement of the machine housing ι, the displacer 24 in the cylindrical bore 18 performs a rotation about the housing axis 26 offset by about i8o ° with respect to the disturbance mass 15 when the machine is unloaded, the direction of rotation of the mass bodies 15, 16, 24, Λ and B and the movement of the machine housing is always the same.

On the housing part (Fig. 7) acts from the reactions of the working part through the transmission of the. forces to be compacted resultant P. Further forces Q and R exerted by the shaft ri of the drive part act on the bearings 13 and 14. These forces can be combined into a resultant S. The center of impact of this housing part for the above-mentioned resulting force S should fall in point 4 according to the invention.

The arrangement and the distribution of the mass of the housing part is advantageously chosen so that the resultant of the two bearing reactions Q and R with the force P falls in the same plane. As a result, the resultant "S" of all three forces P, Q and R also falls into this plane. A change in the size of the force P ₁ as it is caused by the changing degree of compression of the working medium enclosed in the work area thus affects the position of the resultant S no longer influences, but only on its size. Changes in the size of the force do not change the position of the center of the impact. As a result, the slight shifts of the center of the impact caused by fluctuations in the force P are also excluded.

The act on the drive part (Fig. 8)

Bearing reactions Q ₁ and R _± of bearings 13 and 14. Also, these forces together give a resultant T _1, whereby the center of impact of this part must fall again at point 4 for the resulting force T. Finally, the working part 24 (FIG. 9) is acted on by the forces exerted by the roller track 18 of the compressor room and the forces exerted by the agent to be compacted, which together give a resultant P ₁ ; in turn, the center of impact of this resultant P ₁ for the displacement body 24 should fall at point 4.

The point 4 thus represents a point for the entire compressor, which is during the movement the compressor cannot react to the surroundings and is therefore the most suitable point for the suspension of the Machine represents. If the universal joint 6, 7, 8, 9 is designed so that at 'The free movement of the compressor point 4 is at least almost immobile remains, no interfering, periodically changing will be on the solid base 5 Forces exerted, but only the resting force of the weight of the machine. So it is completely excluded that any fluctuations in the carrier 5 arise can, so that no disruptive effects on the wider environment of the machine even during operation Effects can be exercised.

The compressor 3 sucks the agent to be compressed through the line 19 into the suction chamber, which is separated from the pressure chamber by the abutment slide 2, J pressed onto the displacer 24 by means of the spring 28. The compressed medium is conveyed via the check valve 29 (FIG. 2) into the pressure line 20 and from there to the point of consumption. As soon as there is a pressure difference between the suction and pressure side, which z. If, for example, a medium to be compressed is supplied through the line 19, the displacer 24 has to perform work so that it lags the centrifugal weight 15 at an angle greater than 180 ° by an amount corresponding to this work.

The compressor shown in Fig. 3 is also as a machine with a sickle-shaped Trained work space. The housing part consists of the machine housing 30 and the housing 31 of the compressor formed and arranged so that the eccentric rotating Mass 33, which essentially forms the drive part, rotate in the same plane 34 can like the displacer 35. The shaft 36 driving the mass 33 is in the im Machine housing 30 fixedly mounted bearings 37 and 38 and with a pulley 39 provided, which is wedged so obliquely on the Welles that it is in each rotational position of the shaft with its belt means is horizontal. The housing 30 has a spherical one. End piece 40, which is in a spherical pan 41 of the solid support 42 is mounted so that the housing probably has an eccentric oscillating movement can exert, however, at a rotation around the housing centroid by the pin 43 is prevented. The pulley 39 is adjusted with respect to the ball socket 43 in such a way that that the center line of the belt lies in the horizontal plane through the center of the sphere 44 and thus the belt tension 45 cannot exert a moment on the machine housing 30. The working part is from the. The displacer 35 is formed with the weights arranged on both sides.

The whole arrangement is again held according to the invention so that the impact centers the forces which result as the result of the forces exerted on each individual part by the other parts, coincide for each individual part in a common point 44 and that the whole Compressor like that. is hung on that this point 44 remains practically immobile. the individual interference forces (46, 47) can thus act on the ball socket 41 of the solid base 42 no longer exert any moving forces, this only has to absorb the static force of the weight of the machine.

The mode of operation corresponds to the example in FIGS. 1 and 2. Through the mass body 33 the machine housing 30 is set in an eccentric oscillating movement. Under the action of the centrifugal force 47, the displacer 36 in the cylindrical displacement space 48 with its center line in a brought the axis of this cylinder space revolving motion so that -das durcli the Suction line 49 sucked in, compressed means to be compressed in the sickle-shaped working space and is conveyed further through the pressure line 50.

The compressor according to FIG. 4 has two housing parts, a first, which is formed by the machine housing 55, and a second, which is formed by the compressor housing 67 . The drive part in turn consists of the rotor 63 wedged onto the shaft 64 and weight 66. Finally, the working part is represented by the displacer 73. The machine housing 55 is suspended from the universal joint 56, which is connected to a fixed frame 58 by the support 57. The motor 59 is installed in the machine housing 55 in such a way that the stator 60 and the bearings 61 and 62 of the rotor 63 keyed onto the shaft 64 are firmly connected to the machine housing. The arm 65 and the weight-

568007

66. Are made by -. the- shaft 64 in - rotating Movement. The compressor housing 62 is with the pin en .68 _än one end in

■ -. a bearing 69 of the arm 65 and with the the other end 70 in a universal joint 71 firmly connected to the machine housing 55 stored. The arm. 65 forces the compressor housing when it rotates with the shaft 64

67 to a conical movement such that all points of the housing 67 execute flat circles.

In the compressor housing 67, a displacer 72 is again provided, which is "moved by the centrifugal force and forms a sickle-shaped working space into which the medium to be compressed is sucked out of the line 73. The conveyance to the point of consumption takes place through the line 74 their implementation are die'beiden Lei obligations 73 and 74 fixedly connected to the machine housing 55, go but then, in helical windings 75 and 76 on, so that due to this resiliently flexible connecting the terminals 77 and 78 to the compressor housing 67 the circular motion the latter can follow.

Provided that constant forces are constantly exerted on the displacer 72 all centrifugal forces of the vibrating as well as the rotating part could be balanced by the weight 66. However, due to the compression, the Compression means on the displacer 72 and the housing 67 are constantly during one revolution exerted changing forces, so that these masses are delayed in their movement and be accelerated. The reaction of those resulting from these delays and accelerations. Mass forces acts on the housing.67 and on the arm 65 in such a way that the latter no longer can revolve with an unchangeable angular velocity and also on the bearings 61 and 62 exercises reactions. But these reactions have to do with the case! 5 5 a ■ disturbing influence and set the housing in vibratory movements.

According to the invention, the entire compressor "is suspended in such a way that the center of impacts of the forces, which result as the result of the forces exerted on each part by the other parts, coincide for each individual" part in the center of the cardan joint 56, 57. _; As a result, no more disruptive reaction can be exerted on the solid base 5, 8. The by-the variable forces "to be compacted means on the machine housing 55 exerted" blows are thus not transmitted as in previous versions on the solid support, but the puhkt through "in the surge means ^·: aufgehängte- mass of 'the machine housing absorbed and compensated for.

Instead of the previously described cardanic suspension with flexible connecting means on the one hand or pins and bearings on the other hand and the spherical suspension Other suspensions can also be used, for example the conical disk suspension shown in FIGS. The vibrating compressor is suspended from the pivot 80 on which the Conical disk 81 is attached and with its conical surface 82 on the conical surface 83 of the Washer 84 can roll. During this movement, the position of the cone tips remains 85 of the two conical surfaces 82 and 83 unchanged The apex angle of the cones is the supplement of the angle between the common median line of the housing with the disruptive masses and the center of gravity of the housing. This creates between the two conical surfaces line contact.

To prevent the pin 80 from rotating around the center of gravity of the entire machine, can according to FIGS. 5 and 6 in the still Point 85 of the pin 80 a solid or resiliently flexible pin 86 can be provided, the two ends of which are in recesses 87 of the fixed base 88 engages.

All possible flexible building materials, such as B. leather, Balata, or steel bands, are used. be making noises of moving Parts are avoided. The springy, spring-loaded from the compressor housing Flexible tubes are conveniently located near the cardanic suspension des - machine housing connected to the fixed parts in order to avoid excessive bending to avoid the same. "■ · -

The invention offers compared to the ^ stuffing box Compressors according to the old design have the great advantage that they can be operated with very, simple mechanical means can achieve a smooth operation of machines, what so far only through cumbersome and many conditions tied funds could be partially achieved.

Claims (12)

Patent claims: i. From a drive part, a working part and one or more housing parts existing compressor with eccentric oscillating movement, in which the compression by the effect of centrifugal force of the drive part by means of. Transmission driven by centrifugal _ benen; Work part takes place, characterized by ,,, .that the centers of impact of the forces, which are resultants' the on each part · from the remaining parts exerted forces, coincide at one point for each individual part and that the compressor is suspended in such a way that the impact centers remain almost immobile. 2. Compressor according to claim i, characterized in that the machine housing (i) is gimbaled in such a way that its Schwerlinio (26) turns out to be Generating a cone with a vertical axis can move, its tip (4) with the suspension point of the machine housing (1) coincides and its half apex angle is at least the value of the angle (α) between the Center of gravity (26) of the machine housing and the common center of gravity (25) of the interfering masses and the housing or the housing assumes. 3. Compressor according to claim 2, characterized in that the eccentric Vibration of the compressor housing (3 in Fig. 1, 31 in Fig. 3) by eccentric in this . rotatable masses (15, 16 in Fig. i, 33 · in Fig. 3), the axis of rotation compared to the Verdichtergetiäuse in unchangeable Location remains, is generated (Fig. Ι and 3). 4. Compressor according to claim, characterized in that the eccentric vibration of the compressor • housing (67) is generated by an arm (65) mounted with its axis (64) in fixed bearings (61, 62) of the machine housing (55) ( Fig. 4). 5. Compressor according to claim 3, characterized in that the eccentric rotatable mass (15, 16 in Fig. 1) driving motor is arranged in the machine housing and connected to it (Fig. i). 6. Compressor according to claim 3, characterized in that the eccentrically rotatable mass (33 in Fig. 3) is driven in the housing by a motor arranged outside the housing (Fig. 3). 7. Compressor according to claim 6, characterized in that the machine housing eccentrically rotatable mass (33 in Fig. 3), in the suspension point (44). attacking the housing, from the motor is driven (Fig. 3). 8. Compressor according to claim 4, characterized characterized in that the arm supported in the machine housing (65 in Fig. 4) driving motor is also arranged in the machine housing (Fig. 4). 9. Compressor according to claim 4, characterized in that the ^{arm mounted in the 6} <> masohine housing (65 in Fig. 4) driving the motor is arranged outside the machine housing on a solid base (Fig. 4). 10. Compressor according to claim 9, characterized in that the machine housing rotatable arm (65 in Fig. 4), in the suspension point (56) of the machine housing attacking, is driven by the engine (Fig. 4). 11. Compressor according to claim 1, characterized characterized in that the suspension of the machine housing by means of resilient flexible means (7 in Fig. 1) takes place. ,, 12. Compressor according to claim 1, characterized characterized in that the suspension of the machine housing by means of conical disks (Si, 84 in Fig. 5), whose common cone tip (85) in or near the center of the impact takes place (Fig. 5 and 6). Please refer to the sheet of drawings INDEED. GEI) BUCIfT IN IiEtCHSbMJCIiEREt