JPH03296617A - Preventing method of cross talk of tandem resolver - Google Patents

Abstract

PURPOSE:To obtain a highly accurate resolver output from each resolver part by constituting a rotary shaft of a casing and each resolver part of nonmagnetic substance thereby to prevent a cross talk between the resolver parts. CONSTITUTION:A first and a second resolver parts 3, 4 driven with different frequencies are provided in a casing 1. The resolver parts 3, 4 have a rotary shaft 5 which is rotatable to each bearing 2. Moreover, the casing 1 and rotary shaft 5 are made of nonmagnetic metallic material. Therefore, when signals of different frequencies are simultaneously excited to the resolver parts 3, 4 through respective rotary transformers 10, 24, a cross talk resulting from the magnetic flux passing the casing 1 and rotary shaft 5 can be prevented since the casing 1 and rotary shaft 5 are formed of nonmagnetic substance. Accordingly, a highly accurate resolver signal without a cross talk can be obtained from each resolver part 3, 4.

Description

DETAILED DESCRIPTION OF THE INVENTION a. Industrial Application Field The present invention relates to a tandem resolver, and in particular, a novel method for preventing crosstalk between each resolver section and enabling each resolver section to be driven at a different frequency. Regarding improvements.

b. Prior Art There are various types of dual tandem resolvers of this kind that have been used in the past, but to describe a typical one, as shown in FIG. We can cite configurations that were manufactured in-house.

That is, what is indicated by the reference numeral 1 in the figure is a casing that has a cylindrical shape as a whole and has a pair of bearings 2 at both ends, and inside this casing 1 are a second resolver section 3 and a second resolver section 3 that are driven at mutually different frequencies. A second resolver section 4 is provided.

The second resolver section 3 includes a first rotary transformer 6 and a second resolver rotor provided on a rotating shaft 5 rotatably provided in each of the bearings 2, and a first resolver rotor provided in the casing 1. It is composed of a rotating transformer stator 8 and a second resolver stator 9.

The first rotary transformer rotor 6 is provided with a first rotary transformer winding 6a, and the first rotary transformer stator 8 is provided with a first rotary transformer stator winding l! 8a, and the first rotary transformer rotor 6 and the first rotary transformer stator 8 constitute a first rotary transformer 10.

The second resolver rotor is provided with a second resolver rotor winding 11 , and the second resolver stator 9 is provided with a second resolver stator winding 12 .

The second resolver section 4 includes a second rotary transformer rotor 20 and a second resolver rotor 21 provided on a rotating shaft 5 rotatably provided in each bearing 2, and the casing 1.
The second rotary transformer stator 22 and the second
It is composed of a resolver stator 23.

The second rotating transformer rotor 20 is provided with a second rotating transformer-rotor winding 20a, the second transformer stator 22 is provided with a second rotating transformer-stator winding 22a, and the second rotating transformer-stator 20 is provided with a second rotating transformer-stator winding 20a. transformer rotor 2
0 and the second rotating transformer stator 22 constitute a second rotating transformer 24.

The second resolver rotor 21 is provided with a second resolver rotor winding 25 , and the second resolver stator 23 is provided with a second resolver stator winding 26 .

Therefore, when signals of different frequencies are simultaneously excited to each resolver stator section 3.4 via each rotary transformer 10.24, rotation detection (resolver) signals of different frequencies are obtained from each resolver section 3.4. be able to.

Problems to be Solved by the C0 Invention Since the conventional tandem resolver was configured as described above, the following problems existed.

That is, since no magnetic shielding member was formed between each resolver part, if they were excited at the same time at different frequencies, interference would occur between each resolver member, and crosstalk would be added to the resolver 8 force. This was supposed to reduce the performance of the original resolver.

The present invention has been made to solve the above-mentioned problems. In particular, the present invention prevents crosstalk between each resolver section, and reduces crosstalk in a tandem resolver that enables each resolver section to be driven at a different frequency. The purpose is to provide a prevention method.

61 Means for Solving the Problems A method for preventing crosstalk in a tandem resolver according to the present invention includes exciting a pair of resolver sections provided in a casing at mutually different frequencies, and obtaining an output signal from each of the resolver sections. In this tandem resolver, the gauging and the rotating shaft of each resolver section are made of non-magnetic material, thereby preventing crosstalk between the resolver sections.

Further, as another invention, in a tandem resolver in which a pair of resolver parts provided in a casing are excited at mutually different frequencies and output signals are obtained from each of the resolver parts, a first casing part forming the casing is provided. In this method, crosstalk between the respective resolver parts is prevented by a non-magnetic material part provided between the first gauging part and the second gauging part.

Further, as another invention, in a tandem resolver in which a pair of resolver parts provided in a casing are excited at mutually different frequencies and output signals are obtained from each of the resolver parts, a first gauging part forming the casing is provided. and a second casing part, and a magnetic material means provided between each resolver part in the casing to prevent crosstalk between each resolver part. be.

Further, as another invention, in a tandem resolver in which a pair of resolver sections provided in a casing are excited at mutually different frequencies to obtain an output signal from each of the resolver sections, there is a gap between the casing and each resolver section. This method uses a non-magnetic ring provided to prevent crosstalk between each resolver section.

Further, as another invention, in a tandem resolver in which a pair of resolver sections provided in a casing are excited at mutually different frequencies and output signals are obtained from each of the resolver sections, the rotation axis of each of the resolver sections is This is a method in which crosstalk between each resolver part is prevented by the provided non-magnetic cylinder.

Further, as another invention, in a tandem resolver, a pair of resolver sections provided in a casing are excited at different frequencies to obtain an output signal from each of the resolver sections. The rotating shaft is made of a non-magnetic material, a non-magnetic material provided between each casing part forming the casing, a magnetic material means provided between each of the resolver parts, and a non-magnetic material provided between the casing and each resolver part. This structure prevents crosstalk between the resolver parts by a non-magnetic ring and a non-magnetic cylindrical body provided on the rotating shaft.

89 Effect In the crosstalk prevention method for a tandem resolver according to the present invention, the rotating shaft of the casing and each resolver part is made of a non-magnetic material, a non-magnetic material part is provided between each casing part forming the casing, and each resolver part is provided with a non-magnetic material part. A configuration in which magnetic material means is provided between the casing, a non-magnetic ring is provided between the casing and each resolver section, and a non-magnetic cylindrical body is provided on the rotating shaft of each resolver section, the magnetic flux passing through the casing and the rotating shaft are It is possible to block the magnetic flux passing through and floating as leaking magnetic flux, and it is possible to completely prevent crosstalk between each resolver section.

f. Embodiments Hereinafter, preferred embodiments of the method for preventing crosstalk in a tandem resolver according to the present invention will be described in detail with reference to the drawings.

It should be noted that the same or equivalent parts as in the conventional example will be described with the same reference numerals.

1 to 6 are cross-sectional views showing a tandem resolver used in the method for preventing crosstalk in a tandem resolver according to the present invention.

First, in FIG. 1, a casing designated by reference numeral 1 is a cylindrical casing having a pair of bearings 2 at both ends. section 3 and a second resolver section 4 are provided.

The second resolver section 3 includes a first rotary transformer 6 and a second resolver rotor provided on a rotating shaft 5 rotatably provided in each of the bearings 2, and a first resolver rotor provided in the casing 1. It is composed of a rotating transformer stator 8 and a second resolver stator 9.

The first rotary transformer rotor 6 is provided with a first rotary transformer winding 6a, and the first rotary transformer stator 8 is provided with a first rotary transformer stator winding 8a. The rotary transformer rotor 6 and the first rotary transformer stator 8 cause the first rotary transformer 1 to
It constitutes 0.

The second resolver rotor includes a second resolver rotor 2.
11 is provided, and the second resolver stator 9 is provided with a second resolver stator winding 12 .

The second resolver section 4 includes a second rotary transformer rotor 20 and a second resolver rotor 21 provided on a rotating shaft 5 rotatably provided in each bearing 2, and the casing 1.
The second rotary transformer stator 22 and the second
It is composed of a resolver stator 23.

The second rotating transformer rotor 20 is provided with a second rotating transformer-rotor winding 20a, the second transformer stator 22 is provided with a second rotating transformer-stator winding 22a, and the second rotating transformer-stator 20 is provided with a second rotating transformer-stator winding 20a. transformer rotor 2
0 and the second rotating transformer stator 22 constitute a second rotating transformer 24.

The second resolver rotor 21 is provided with a second resolver rotor winding 25 , and the second resolver stator 23 is provided with a second resolver stator winding 26 .

Further, the casing 1 and the rotating shaft 5 are made of a non-magnetic material made of non-magnetic metal.

Therefore, for each resolver section 3.4, each rotary transformer 1
When signals of different frequencies are simultaneously excited through 0.24, crosstalk due to magnetic flux passing through the casing 1 and the rotating shaft 5 can be prevented because the casing 1 and the rotating shaft 5 are made of non-magnetic material. , and a highly accurate resolver signal without crosstalk can be obtained from each resolver section 3.4.

Next, in the case of the second embodiment shown in FIG. 2, the same parts as in FIG. 2 casing parts 1b, each casing part 1a, l
A non-magnetic material portion 1c is provided between b.

Therefore, this non-magnetic material 1c can prevent crosstalk caused by magnetic flux flowing through the casing 1.

Next, in the case of the third embodiment shown in FIG. 3, the same parts as in FIG. , a fixed magnetic shaft 30a and a rotating magnetic shaft 30b constituting a ring-shaped magnetic material means 30 are provided.

Therefore, the non-magnetic material part 1c and the magnetic material means 30 absorb the magnetic flux flowing through the casing 1 and the leakage magnetic flux between the windings 11.12 and 25.26 between each resolver part 3.4, thereby reducing crosstalk. It can be prevented.

Next, in the case of the fourth embodiment shown in FIG. 4, the same parts as in FIG. , a non-magnetic ring 31 made of a non-magnetic material is interposed, and each resolver part 3, 4
This prevents crosstalk due to the flow of magnetic flux between the gauging 1 and the gauging 1.

Next, in the case of the fifth embodiment shown in FIG. 5, the same parts as in FIG. is provided with a non-magnetic cylindrical body 32 fitted onto the rotating shaft 5.

Therefore, this non-magnetic cylindrical body 32 can prevent crosstalk between the resolver parts 3 and 4 due to the magnetic flux flowing through the rotating shaft 5.

Furthermore, in the case of the sixth embodiment shown in FIG. 6, crosstalk is prevented using all the configurations in FIGS. Description and operation will be omitted.

g1 Effects of the invention Since the method for preventing tallostoke in a tandem resolver according to the invention is configured as described above, the following effects can be obtained.

That is, the rotating shaft of the casing and each resolver part is made of a non-magnetic material, the non-magnetic material is provided between each casing part forming the casing, the magnetic material means is provided between each resolver part, and the casing and each resolver part are provided with a magnetic material means. With a configuration in which a non-magnetic ring is provided between the parts and a non-magnetic cylindrical body is provided on the rotating shaft of each resolver part, floating magnetic flux passing through the casing, magnetic flux passing through the rotating shaft, and leakage magnetic flux can be blocked. By preventing crosstalk, highly accurate resolver outputs can be obtained from each resolver section.

[Brief explanation of drawings]

1 to 6 are cross-sectional views showing each embodiment of a tandem resolver to which the method for preventing crosstalk in a tandem resolver according to the present invention is applied, and FIG. 7 is a cross-sectional view showing a conventional tandem resolver. 1 is a casing, 1a and lb are casing parts, 1c is a non-magnetic material part, 3.4 is a resolver part, 5 is a rotating shaft, 30 is a magnetic material means, 31 is a non-magnetic ring, and 32 is a non-magnetic cylindrical body . Figure 1 Figure 2 Figure 3 (1-Casing (to lb) is casing part F (1c) is non-magnetic material part (3, 4) is resonating part (5) 1 Rotating shaft (30) is magnetic material means

Claims (6)

[Claims] (1) In a tandem resolver in which a pair of resolver sections (3, 4) provided in a casing (1) are excited at mutually different frequencies, and output signals are obtained from each of the resolver sections (3, 4). The casing (1) and the rotating shaft (5) of each resolver part (3, 4) are made of non-magnetic material to prevent crosstalk between each resolver part (3, 4). A method for preventing crosstalk in a tandem resolver. (2) In a tandem resolver in which a pair of resolver parts (3, 4) provided in a casing (1) are excited at mutually different frequencies, and output signals are obtained from each of the resolver parts (3, 4). , a first casing part (1a) forming the casing (1);
A crosstalk of a tandem resolver characterized in that crosstalk between each resolver part (3, 4) is prevented by a non-magnetic material part (1c) provided between the second casing part (1b) and the second casing part (1b). How to prevent talk. (3) In a tandem resolver in which a pair of resolver parts (3, 4) provided in a casing (1) are excited at mutually different frequencies, and output signals are obtained from each of the resolver parts (3, 4). , a first casing part (1a) forming the casing (1);
and a non-magnetic material part (1c) provided between the second casing part (1b) and a magnetic material means (30) provided between each resolver part (3, 4) in the casing (1). A method for preventing crosstalk in a tandem resolver, characterized in that crosstalk between each resolver section (3, 4) is prevented by: (4) In a tandem resolver in which a pair of resolver sections (3, 4) provided in a casing (1) are excited at different frequencies to obtain an output signal from each of the resolver sections (3, 4). , The non-magnetic ring (31) provided between the casing (1) and each resolver part (3, 4) allows
3, 4) A method for preventing crosstalk in a tandem resolver, characterized in that crosstalk between the two resolvers is prevented. (5) In a tandem resolver in which a pair of resolver sections (3, 4) provided in a casing (1) are excited at different frequencies to obtain an output signal from each of the resolver sections (3, 4). , The non-magnetic cylinder (32) provided on the rotating shaft (5) of each resolver part (3, 4) allows each resolver part (3, 4) to
A method for preventing crosstalk in a tandem resolver, characterized in that crosstalk between the resolvers is prevented. (6) In a tandem resolver in which a pair of resolver sections (3, 4) provided in a casing (1) are excited at mutually different frequencies, and output signals are obtained from each of the resolver sections (3, 4). , the casing (1) and the rotating shaft (5) of each of the resolver parts (3, 4) are made of a non-magnetic material, and the casing (1)
), a non-magnetic material part (1c) provided between each of the casing parts (1a, 1b), a magnetic material means (30) provided between each of the resolver parts (3, 4), and the casing (1).
and the non-magnetic ring (31) provided between each resolver part (3, 4) and the non-magnetic cylinder (32) provided on the rotating shaft (5), A method for preventing crosstalk in a tandem resolver, characterized in that crosstalk is prevented.