NO167227B - VALVE ARRANGEMENT FOR PUMP OR COMPRESSOR. - Google Patents

Abstract

A valve arrangement for compressor with oscillating piston wings (116b) has a series of mutually angularly displaced discharge slots (119) arranged in a radially extending end wall (113) between working chamber of the machine and on oppositely disposed discharge chamber (111b). The discharge slots (119) are controlled by their respective spring-loaded valve member (112b). The valve member (112b) is inserted in the end wall (113) in a groove (121) which has a minimum opening directed towards the working chamber and a maximum opening directed towards the discharge chamber (111b). A valve seat (121a) is arranged between these openings. The inner surface of the valve is flush or substantially flush with the adjacent inner surface of the working chamber.

Description

Device for soft iron instruments.

The present invention relates to a device for soft iron instruments which are mainly used as voltmeters, ammeters and other types of measuring instruments, as well as the principle is also used for some electromagnetic relays.

There are known soft iron instruments which comprise fixed and movable ferromagnetic parts, where the fixed part is provided with a spde which, when it is current-carrying, produces magnetic fluxes that pass through the fixed and movable part and the air gap between these and thereby produces a torque on the movable the part,, which is provided with a pointer, the output of which is proportional to the current in the coil.

A known soft iron instrument uses a cylindrical coil and a movable core which is placed asymmetrically in relation to the axis of the coil (cf. West German patent no. I.083.42I and 972.524). The fixed part is mounted on the inside of the coil.

The movable element<*>'s axis of rotation coincides with the coil axis and the movable element undergoes a circular movement at the stroke. A soft iron instrument is also known, where the pivot axis of the movable part is perpendicular to the axis of the coil and where the movable part is adapted to enter the inside of the coil (cf. West German patent no. I.O92.562). Next to this, there are known soft iron instruments where e.g. the coil lies around the fixed ferromagnetic part, and where the movable part is placed on the outside of the coil and interacts with the fixed ferromagnetic part (cf. West German patent no. 1,006,062). The above-mentioned soft iron instruments are associated with the following disadvantages. The magnetic flux undergoes a significant spread and is therefore not effectively utilized, the weight of the moving part affects the suspension and the sensitivity is relatively low. One purpose of this invention is to eliminate the above-mentioned disadvantages and to provide a soft iron instrument which has a high sensitivity, a simple design and which is easy to assemble and adjust. Another purpose of the invention is to provide a soft iron instrument with high accuracy and with an approximately linear scale, and where the instrument is shielded from external magnetic influences. Yet another object of the invention is to provide an instrument with a depressed zero point and with a large scale covering more than 270°. A further purpose of the invention is to provide a device which in large. degree can be used in many different frame or case types for soft iron instruments. The aim of the invention is to make maximum use of the moving part's surface for increasing the coil's inductance. ;This is achieved by a device for a soft iron instrument, comprising fixed and movable ferromagnetic parts, where the fixed part is provided with a coil whose produced magnetic flux passes through the fixed and movable part and the air gaps between these and thereby produces a torque on the movable part which has an asymmetrical design in relation to the axis of rotation and where the two pole shoes of the fixed part have a different design and asymmetrical placement in relation to the axis of rotation of the movable part, according to the invention in that both pole shoes are provided with slots in which the plate-shaped movable forromagnetic part can turn itself, so that a varying part of its surface is covered by the pole shoes in the different launch angles, while the asymmetric design of the pole shoe and the moving part are utilized to give the instrument a desired characteristic. The invention is further characterized by the fact that the ratio between the distance from the pivot axis to the point closest to the axis on the edge of the movable part to the distance from the same pivot axis to the point furthest from the axis on the same edge is kept in the range 0.1 - 1, and that the distance from the points and those of the edges of the pole shoes that lie opposite each other to the pivot axis is in the range 0.1-3 relative units, where a relative unit denotes the maximum distance from the edge of the movable part to the pivot axis a . ;According to the invention, an increase in the deflection angle for the pointer can be achieved by the pole shoe placed farthest from the axis of rotation surrounding the other pole shoe with an angle of 320°. The invention is further characterized in that the pole shoes are designed so that, at full extension of the movable part, the ratio between the area of the gap formed by the movable part and the nearest pivot axis located at the pole shoe and the area of the gap formed by the movable part and the pole located farthest from the axis of rotation is in the range 0.5 - 10. If the device is to be used in a voltmeter, according to the invention it is preferable that the coil is wound on a wire which has a specific resistance greater than 0.03 <oh>mmm<m>; Other purposes and advantages of the invention are to be explained in more detail in connection with the following description and drawings, and where ;fig. 1 and 2 are elevations of the device which according to the invention can be used in e.g. an ammeter or voltmeter with an approximately linear scale,. ; fig. 3> 4> 5> 6, 7 and 8 are drawings of possible embodiments of the movable iron part, ;fig. 9 is an elevation of the device which according to the invention can be used for an ammeter or voltmeter with a compressed scale and fig. 10 is an elevation of the device which, according to the invention, can be used for an instrument with an opening angle of up to 320°. ;As shown in fig. 1 and 2, the fixed part comprises a core lwhich is surrounded by a coil 2 and pole shoes 5> 6 which are both fixed to the core by means of screws 3 and 4- ;The pole shoes 5 and 6 are formed with a longitudinal slot ;7. Between the pole shoes 5 and 6 there is placed a movable iron part 8. A spindle 9 with an associated pointer 10 and other elements such as e.g. a spring and the like (not shown in the drawing), is placed near the pole shoe 5 which has a slot 11 with an opening 12 for the passage of the spindle 9 and for an easier mounting of the device. The pole shoe 6, which is farthest from the pivot axis of the moving part and which will therefore be called "outer pole shoe", and the movable part 8 forms an air gap 13> while the pole shoe 5, which is closest to the pivot axis of the movable part and which will therefore be called "inner pole shoe", and the movable part 8 forms an air gap 14- In order to achieve high sensitivity over a significant angle of attack, the movable part 8 is asymmetrical in relation to its pivot axis 9-; The movable part 8 moves in the gap 7 in the pole shoes 5 and 6, whereby it changes the permeance of the gaps 13 and 14 by changing the area of the gaps. The permeance change of the air gaps 13 and 14 is dependent on the rotation angle of the moving part. In the case where ;where G-j^ is the permeance of the gap 13, G-^ is the permeance of the gap 14 and a is the angle of rotation of the moving part 8. In this case, the torque is determined by the formula ;Where JW is the ampere recovery number of the coil 2. ;It is desirable in this case that the ratio between the permeance of the gaps with full opening angle (a = «max) is chosen so that: ;where G^max is the maximum permeance of the gaps 13 and 14, respectively, at full opening angle. ;Another case is when ;in which case the torque is determined by It is desirable in this case that the ratio between the permeance of the gaps at a = a III a X is chosen so that Yet another case arises when in which case the torque is determined by ;It is desirable in this case that the ratio between the permeance of the gaps at a = a Illa. is chosen so that ;An important feature of all the cases mentioned above is the utilization of almost the entire moving part's surface (80-95$ at a = a ) for creating the air gaps 13 and 14, which enables a sufficient increase of the gaps permeance at a certain weight of the moving part, so that the device's sensitivity can be increased. ;Gap permeance is known to depend on both the length and area of the gap. Due to the fact that the length determined by the distance between the movable part and the fixed pole shoes is usually chosen as small as possible from design considerations, the above-mentioned dependencies can be mainly determined as the ratio of the areas of the gaps formed by the movable part in combination with the inner and outer Polish shoes. As a consequence of this, it is desirable that the ratio between the distance from the pivot axis to the point closest to the axis on the edge of the moving part to the distance from the same pivot axis to the point furthest from the axis on the same edge is kept in the range 0 ,1 - 1 and that the distance from the points on the edges of the pole shoes that lie opposite each other to the pivot axis is in the range 0.1-3 relative units, where a relative unit denotes the maximum distance from the edge of the movable part to the pivot axis. As mentioned above, the permeance of the gap can also be changed by changing the length of the gap. With this purpose in mind, the pole shoes 5 and 6 are arranged so that they have a certain angle in relation to the plane of the moving part. ;The magnetic gaps 13 and 14 between each of the two split poles 5 and 6 and the movable iron part 8 (see Fig. 1), are symmetrical in relation to the plane formed by the movable part 8, when it rotates. Because of this, the forces produced by the mutual influence of the pole shoes and the movable part and which are directed along the axis of rotation of the movable part are balanced. The pole shoes 5 and 6 cover almost the entire area of the moving part and thus also serve to shield against external magnetic influences. Adjustment of the device can be easily done by e.g. to rotate the pole shoes 5 and 6 in relation to the points 3 and 4 where they are attached to the core 1. To achieve the above-mentioned conditions, the pole shoes and the movable part can be given different designs. ;The design is chosen in accordance with the desired scale type. Fig. 3, 4, 5, 6, 7 °S 8 shows different embodiments of the movable part 8 which is placed on the spindle g. The design of the movable part shown in fig. 3> can be recommended as the simplest for in instruments with a square scale. ;The movable iron part shown in fig. 4 enables an increase in the scale angle in comparison with fig. 3*

The design of the movable iron part shown

on fig. 5> can be recommended for use in instruments with a relatively evenly divided scale.

The design of the movable part shown in fig. 6, can be recommended for use in instruments which are equipped with a relatively heavy pointer which will be balanced by the piece of the moving part furthest from the axis.

The design of the movable iron part shown

on fig. 7> can be recommended for use in instruments with a scale angle of up to 320°.

The design of the movable iron part shown

on fig. 8, can be recommended for use in instruments with a compressed scale at the end.

According to the invention, it is recommended that the parts are designed so that, at full extension of the movable part, the ratio between the area of the gap formed by the movable part and the pole shoe located closest to the axis of rotation and the area of the gap formed by the movable part and the pole shoe placed farthest from the pivot axis is in the range 0.5 - 10.

It is also desirable that the weight of the moving system's active parts constitutes 30 - 6°$ of the moving system's constructive parts.

According to this invention, the moving system can both be stored on a fixed spindle and suspended in bands, and any type of damper (air, liquid or inductive) can be used. None of these elements are shown in the drawings, as they do not form any part of the invention, and in the description they are covered by the term "constructive elements".

Fig. 9 shows an embodiment of the fixed iron part's outer and inner pole shoes for the case where it is desirable to have a scale with a compressed part. The reference numbers of the various parts

on fig. 9 is in accordance with what is shown in fig. 1. When comparing

ning of the instruments in fig. 9 and 1, it appears that the difference be-

states that the outer pole shoe 6 in fig. 7 is made with a notch 15.

Of course, such notches or protrusions can be made

on both the outer and inner pole shoe and also on the moving part and the desired area and weight ratios should be kept within certain limits.

In fig. 10, according to the invention, an instrument is shown where the pointer's deflection angle is greater than 2" J0°. All the reference numbers in fig. 10 are in accordance with what is shown in

fig. 1. By comparing fig. 10 and fig. 1, it appears that the difference consists in that the outer pole shoe 6 in fig. 10 is. designed to surround the inner pole shoe.5 with an angle of up to 320°.

If the device is to be used in connection with instruments where this must have a high resistance, e.g. a voltmeter, it is desirable to wind the atgs coil with a wire with a higher specific resistance than 0.03onmmm<m>—} e.g. manganin. This makes it possible to avoid an additional resistance and to eliminate temperature errors that occur due to the copper's temperature coefficient.

Claims (5)

1. Device for a soft iron instrument, comprising fixed (1, 5> 6) and movable (8) ferromagnetic parts, where the fixed part is provided with a coil (2) whose produced magnetic, flux pas- sees through the fixed and movable part and the air gaps (13, 14) between these and thereby produces a torque on the movable part which has an asymmetrical design in relation to the pivot axis (9), and where the fixed part's two pole shoes (5>6) have different design and asymmetrical location in relation to the pivoting axis of the movable part, characterized in that both pole shoes are provided with slits (7) in which the plate-shaped movable ferromagnetic part can rotate, so that a varying part of its surface is covered by the pole shoes in the different deflection angles , while the asymmetric design of the pole shoe and the moving part are utilized to give the instrument a desired characteristic. 2. Device according to claim 1, characterized in that the asymmetric movable part (8) is designed so that the ratio between the distance from the pivot axis (9) to the point closest to the axis on the edge of the movable part (8) to the distance from it. same pivot axis to the point furthest from the axis on the same edge, is kept in the range 0.1 - 1. 3- Device according to claim l<q>g 2, characterized in that the pole shoes (5, 6) are designed so that the distance from the points on the edges of the pole shoes which lie opposite each other to the pivot axis (9) is in the range 0, 1-3 relative units, where a relative unit denotes the maximum distance from the edge of the moving part (8) to the pivot axis (9) • 4. Device according to any one of the preceding claims, characterized in that the asymmetric location of the pole shoes (5, 6) in relation to the axis of rotation (9) is achieved by the farthest from the axis of rotation (9) placed pole shoe (6) surrounds pole shoe (5) over an angle of 320°, (fig. 10). 5. Device according to any of the preceding claims, characterized in that the pole shoes (5 > 6) are designed so that, when the movable part (8) is fully extended, the ratio between the area of the gap formed by the movable the part (8) and the pole shoe (5) placed closest to the pivot axis (9) and the area of the gap formed by the movable part (8) and the pole shoe (6) placed farthest from the pivot axis (9) is in the range of 0.5 - 10.