JPS6146441Y2 - - Google Patents

Description

[Detailed description of the invention] This invention relates to a rotary viscometer that measures the viscosity of a fluid, and more specifically, the invention relates to a rotary viscometer that measures the viscosity of a fluid. The present invention relates to a type of viscometer that measures the viscosity of a fluid by utilizing the fact that resistance changes depending on the viscosity of the fluid.

Traditionally, rotational viscometers transmit driving force to a rotating body via an elastic body, and indicate viscosity based on the deformation of the elastic body due to the rotational resistance of the rotating body that occurs in response to the viscosity of the fluid. were commonly used. In this type of rotational viscometer, the driving electric motor, elastic body, and rotating body are mechanically connected, so if an excessive load is applied to the rotating body for some reason, the There was a drawback that the electric motor could become overloaded, causing burnout of the electric motor and a more serious accident due to this.

In addition, the entire device that drives the rotating body for viscosity detection is supported so that it can rotate against the elastic force of the elastic body, and the rotation angle of the drive device is proportional to the amount of resistance that the rotating body receives, and in turn, to the viscosity. Some viscometers have been used to measure viscosity by utilizing this phenomenon, and some of these viscometers have a magnetic coupling interposed between the rotating body for viscosity detection and the drive device. In this device, if the rotation of the rotating body is blocked for some reason, the magnetic coupling will slip and the drive device can continue rotating, so the above-mentioned burnout of the electric motor etc. is prevented, but the drive device Due to the need to support the entire device in a rotatable manner, the device inevitably becomes large and complex, and the entire device is prone to rotational vibrations, requiring special consideration to stabilize the viscosity indication. .

The present invention was made with the aim of eliminating the drawbacks of the above-mentioned prior art, and its gist is that a rotating body rotating in a fluid whose viscosity is to be measured and an electric motor driving the rotating body, A first rotor in which at least one permanent magnet is arranged and fixed axially with respect to a rotational center line, and a second rotor made of a conductive material facing the permanent magnet with a predetermined gap therebetween. The two rotors are connected by a magnetic coupling means, and slippage of the magnetic coupling means (rotation of the two rotors The viscosity of the fluid is measured by utilizing the fact that the slip s is expressed as s=(n ₁ -n ₂ )/n ₁ when the velocity is expressed as n ₁ and n ₂ .

Embodiments will be described in detail below based on drawings showing examples.

In FIG. 1, a housing 1 is bolted to a fluid tank T or a frame fixed thereto, and a cover 2 bolted to the top of the housing 1 has an electric motor 3 equipped with a speed reducer attached thereto. There is. As the electric motor 3, it is desirable to use one that rotates at a constant speed as much as possible.

The output shaft 4 of the electric motor 3 is a serration shaft, and is slidably fitted into a serration hole 5b provided in a boss portion 5a of the rotor 5. The rotor 5 is a disk made of silicon steel and has a flat lower surface, and a boss portion 5a is connected to an adjusting member 7 via a bearing 6.
is maintained. The bearing 6 is of a type that can receive not only a radial load in a direction perpendicular to the axis of the rotor 5 but also a thrust load in the axial direction. The adjusting member 7 has a male thread 7b on the outer periphery of the boss portion 7a, and this male thread 7b is screwed into a female thread 2b provided on the cylindrical portion 2a hanging from the lower surface of the cover 2, so that the cover 2 is maintained. An opening 1a is provided in the side wall of the housing 1, and by inserting a finger through the opening 1a and rotating the adjustment member 7, the adjustment member 7, the bearing 6, and the rotor 5 can be moved in the axial direction. is possible. A notch 7c is carved in the outer circumference of the adjustment member 7 in a direction parallel to the axis.
In addition to facilitating the rotation of the adjustment member 7 by fingers, the locking pawl 8 made of an elastic material and screwed to the housing 1 is engaged with the notch 7c, thereby allowing the adjustment member 7 to freely rotate. is being prevented.

A rotating shaft 9 is disposed passing through a boss portion 1b provided at the center of the bottom wall of the housing 1. The rotating shaft 9 is held in the housing 1 via a bearing 10 that can receive not only a radial load but also a thrust load, and a portion that projects downward from the housing 1 is supported by a support tube 12 and a bearing 13. There is. The support cylinder 12 also serves to protect the bearing 13 from splashes of the fluid L, but for the sake of completeness, the bearing 13 is of a sealed type. A disc-shaped rotor 14 made of a non-magnetic material is fixed to the upper end of the rotating shaft 9. The rotor 14 is concentrically opposed to the rotor 5 described above, and an appropriate number of permanent magnets 15 are arranged at equal intervals on the outer periphery of the surface facing the rotor 5 by adhesive or other means. The location is fixed. Rotor 14 and rotor 5
is positioned such that the rotor 5 rotates across the magnetic flux of the permanent magnet 15 and the gap between the rotor 5 and the permanent magnet 15 does not change at all rotational positions. On the other hand, a rotating blade 16 for viscosity detection is fixed to the lower end of the rotating shaft 9.

A coil 17 is attached to the inner surface of the side wall of the housing 1 surrounding the outer periphery of the rotor 14, and a pulsed current is generated in the coil 17 every time the above-mentioned permanent magnet 15 passes near the coil 17. This coil 17 is connected to a viscosity indicating device 20. The viscosity indicator 20 includes a pulse counter 21, a conversion circuit 22, and a viscosity indicator (not shown).The pulse counter 21 counts the number of current pulses generated in the coil 17, and calculates the result. is converted into a viscosity by a conversion circuit 22, and the viscosity indicator (not shown) provided outside the housing 1 indicates the viscosity. In this embodiment, both the pulse counter 21 and the conversion circuit 22 are digital circuits, and the viscosity is digitally indicated on the viscosity display section, but the current generated in the coil 17 is processed in an analog manner to calculate the viscosity. It is also possible to use a viscosity indicating device. Next, the operation will be explained.

The electric motor 3 is rotated with the rotating blade 16 immersed in the fluid L whose viscosity is to be measured. Electric motor 3
When the rotor 5 rotates, the rotor 5 rotates while cutting off the magnetic flux of the permanent magnet 15, an electromotive force is generated in the rotor 5 due to electromagnetic induction, and an eddy current flows in a direction that prevents relative rotation with the permanent magnet 15. That is, the rotor 14
receives rotational torque from the rotor 5, and is rotated in the same direction as the rotor 5. As a result, the rotating blades 16 connected to the rotor 14 by the rotating shaft 9 rotate in the fluid L, but the rotational resistance of the rotating blades 16 corresponds one-to-one to the viscosity of the fluid. Also, since the slip between the rotor 14 and the rotor 5 changes in one-to-one correspondence with the load torque of the rotating shaft 9, even if the electric motor 3 is always rotating at a constant speed, the rotation speed of the rotating blade 16 will change. will change as the viscosity of the fluid changes. That is, if the viscosity increases, the rotational speed of the rotary blade 16 decreases, and conversely, if the viscosity decreases, the rotational speed increases.

Therefore, the viscosity of the fluid L can be determined from the rotational speed of the rotating blade 16. Rotating blade 16
The rotation speed of the rotor 14 is the same as that of the rotor 14 which is directly connected to the rotor blades 16 by the rotation shaft 9. The pulse counter 21 counts the number of permanent magnets 15 passing near the coil 17 fixed to the housing 1. And the result is conversion circuit 2
The viscosity is converted into viscosity in Step 2, and the viscosity is indicated to the viscosity indicator.

Further, the viscosity indication value can be adjusted by rotating the rotating blade 16 in a fluid of known viscosity and rotating the adjusting member 7 with a finger against the locking force of the locking pawl 8. This can be done by moving the rotor 5 closer to or further away from the permanent magnet 15 until the value is equal to the correct value.

The embodiments described in detail above are illustrative of the present invention, and the present invention is not limited thereto, and various modifications are possible.

For example, the rotating body for viscosity detection may be a simple disk or round bar instead of a rotating blade with high rotational resistance, and a plurality of rotating bodies with different rotational resistances may be prepared, It is possible to measure a wide range of viscosities by appropriately exchanging these according to the viscosity of the fluid.

In addition, since the above embodiment is used for fluids with relatively high viscosity, the rotor 5 is made of a special material such as silicon steel, which has a high relative magnetic permeability and a low coercive force (low residual magnetism). It is made of conductive material to increase the magnetic coupling force, but when used for fluids with relatively low viscosity,
The rotor 5 can also be made of ordinary conductive materials such as aluminum and copper.

Also, it is not necessary to arrange multiple permanent magnets at equal intervals around the outer periphery of the rotor; instead, one relatively large permanent magnet can be arranged at the center of the first rotor, so that lines of magnetic force are placed around the outer periphery of the rotor. It is also possible to form projections or ridges that converge and guide in the direction towards the second rotor.

It is also possible to make the shape of the rotor cylindrical, and as shown in FIG. It is also possible to use a combination of a large number of permanent magnets 33 fixed thereon. In the case shown in FIG. 2, many permanent magnets can be arranged in a rotor with a relatively small diameter, so the viscometer can be made smaller, and the rotor 31 can be made smaller.
Alternatively, since there is little change in the gap between the permanent magnet 33 and the rotor 31 when either of the rotors 32 is moved in the axial direction, there is an advantage that the viscosity indication value can be adjusted with high precision. are doing.

Furthermore, in the embodiment, the rotational speed of the rotor 5 on the motor 3 side is always assumed to be constant, and by measuring only the rotational speed of the rotor 14 on the rotating blade 16 side, the difference between the two rotors is determined. Since the slip was detected and the rotational speed of the rotor 14 was measured using the magnetic force of the permanent magnet 15, the slip measuring device was significantly simplified and manufacturing costs were reduced. It is also possible to measure the rotational speeds of both rotors together using a known rotational speed measuring device and thereby detect the slippage between the two rotors.

As described in detail above, the present invention connects the rotating body for viscosity detection and the driving electric motor that rotates it through a coupling means that utilizes electromagnetic force, so that it is possible to prevent foreign objects from entering the rotor. Even if the rotation of the rotor is blocked due to winding or other reasons, the motor can continue to rotate, and there is no risk of burning out the motor as in conventional rotational viscometers, and the viscosity This produces an effect that can significantly improve the safety of the device. In addition, since the viscosity can be determined by measuring the rotational speed of the rotating body, the configuration of the electrical part of the device (the part that measures the rotational speed, converts it to viscosity, and gives instructions) is extremely simple. Furthermore, since the driving device such as the electric motor can be fixed to the fixed member, the structure of the mechanical part is simple and compact, which results in the effect of reducing the manufacturing cost of the device. In addition, when using the relationship between the amount of deformation of an elastic body and rotational torque as in the past, there is a limit to the elastic deformability of the elastic body, so the range that can be measured with one rotating body for viscosity detection However, when measuring viscosity using a rotor, permanent magnet, and slip as in the present invention, this slip and rotational torque generally have a linear relationship over a very wide range. Therefore, it is possible to accurately measure viscosity over a wide range with a single rotating body. Moreover, there is no need to interpose an elastic body between the viscosity detection rotating body and the drive device, and there is no need for the entire drive device to be rotatably held by an elastic body, so there is almost no risk of the device causing rotational vibration. This allows for stable viscosity measurements.

[Brief explanation of the drawing]

FIG. 1 is a partially sectional front view showing an embodiment of the present invention. FIG. 2 is a front sectional view showing only the main parts of another embodiment of the present invention. 1... Housing, 2... Cover, 3... Electric motor with reducer, 4... Output shaft, 5... Rotor, 6
... Bearing, 7 ... Adjustment member, 8 ... Locking claw, 9 ...
...Rotating shaft, 10...Bearing, 12...Support cylinder, 13
... bearing, 14 ... rotor, 15 ... permanent magnet,
16... Rotating vane, 17... Coil, 20... Viscosity indicator, 21... Pulse counter, 22...
Conversion circuit, 31, 32... rotor, 33... permanent magnet.

Claims (1)

[Scope of utility model registration request] A first rotor having at least one permanent magnet arranged and fixed axially symmetrically with respect to its own rotational center line; One of the two rotors is rotated by an electric motor that is immovably supported by a fixed member, and the other is connected to a rotating body that is immersed in the fluid whose viscosity is to be measured. and a rotational speed detection device for detecting the rotational speed of the rotating body, a calculation device for calculating viscosity based on the detected rotational speed, and an indicating device for indicating the calculated viscosity. A rotational viscometer featuring: