SE527641C2 - Magnetic field forming device for displacement sensor, has annular spacer fitted over magnet, and attached to side wall of tubular portion, to fix central axis of magnet in prescribed position in tubular portion - Google Patents

Abstract

A shaft has a tubular portion with an opening, that has side wall surrounding a columnar interior space. A rod-form magnet that generates magnetic field, is inserted into the interior space and fixed to the tubular portion. An annular spacer that is fitted over the magnet and attached firmly to side wall of tubular portion, fixes central axis of the magnet in prescribed position within tubular portion. An independent claim is also included for displacement sensor.

Description

Fixed within the tubular member with an adhesive, such as an epoxy resin.

In this type of displacement sensor, surface treatment of the permanent magnet is difficult, and therefore it is difficult to mount the permanent magnet directly on the movable element, such as the aforementioned drive shaft of the intake exhaust valve. Therefore, in the invention described in Japanese Unexamined Patent Application Publication 2001-263319, a device is used whereby the tubular element is attached to the detection blank, and the permanent magnet is housed in and fixed to the tubular element. With this arrangement, the permanent magnet must be arranged according to a predetermined position within the tubular element, typically a position in which the central axis of the permanent magnet matches the central axis of the tubular element (in other words a coaxial position with the tubular element). the element). However, with the assembly method described in Japanese Unexamined Patent Application Publication 2001-263319, in which an adhesive is used to fix the permanent magnet inside the tubular member, it is difficult to align the central axis of the permanent magnet with the central axis of the tubular member with precision. .

In addition, with this assembly method, a considerable amount of time is required for the adhesive to cure, and hence the assembly process is slow.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a magnetic field forming device and a displacement sensor using the same in which a magnetic element, such as a permanent magnet, can be mounted in a predetermined position with a high degree of precision.

Another object of the present invention is to facilitate the mounting operation of the magnetic element.

A magnetic field forming device for providing a magnetic field in an outer space according to 2 2005-09-26 10:00 V: \ _ NoOrganisation \ HILLFORT INTERNATIONAL \ PATENT \ _NoFamily \ SE \ 21019366 \ 2l019366 ApplicationteztToInstructor CH 2005-09-16 1 The present invention comprises: a shaft having a tubular portion having a side wall surrounding a columnar interior space, and an opening provided at one end of the tubular portion; a rod-shaped magnetic element, for generating the magnetic field, which is inserted into the inner space of the tubular part of the shaft and fixed to the tubular part; and an annular spacer which is fitted over the magnetic element and fixed to the side wall of the tubular member, thereby fixing a central axis of the magnetic element in a predetermined position within the tubular member.

In this magnetic field-forming device, the annular spacer, which fits over the rod-shaped magnetic element, tightly touches the side wall of the tubular part of the shaft, thereby fixing the central axis of the magnetic element in a predetermined position in the interior space. of the tubular part (eg the position of the central axis of the interior space). Hence, the central axis of the magnetic element, by means of a simple operation performed during assembly, can fit the annular spacer over the magnetic element and insert the magnetic element into the inner space of the tubular part from the opening. at one end of the shaft, be positioned in the predetermined position within the interior space with a high degree of precision.

In a preferred embodiment, the rod-shaped magnetic element assumes a shape in which the outer diameter varies axially (e.g. a spindle shape in which the central location is thickest). The inner space of the tubular part of the shaft is formed with a size and shape that suits the thickest placement of the magnetic element. Thus, the magnetic element touches the side wall of the tubular portion of the shaft tightly at its thickest location. The annular spacer is then fitted over a simple predetermined location on the ZÛOS-09-26 10:00 V: \ _ N0Organi5ati0n \ WXLLFORT INTERNATIONAL! Pat.

As a result, the central axial position of the magnetic element is fixed by the thickest placement of the magnetic element and the annular spacer. According to this arrangement, the central axial position of the magnetic element can be fixed in a predetermined position within the tubular part by means of an extremely simple operation, performed during assembly, to fit the simple annular spacer over the aforementioned simple predetermined position of the tubular member. the magnetic element, and insert the magnetic element into the inner space of the tubular part.

In a preferred embodiment, a stopper is provided near the opening in the tubular part to fix the magnetic element within the tubular part so that the magnetic element does not move in the direction of the central axis. According to this arrangement, the magnetic element can be fixed within the shaft entirely by means of a simple operation, performed during assembly, to insert the magnetic element into the inner space of the tubular part of the shaft, and forming the stopper in the vicinity of the opening so that the magnetic element does not fall out of the tubular part.

In a preferred embodiment, the spacer is located near the opening of the tubular member, and one or more holes or grooves are provided in the spacer. The stopper is provided near the opening in a position that does not block the hole or groove.

In a preferred embodiment, one or more holes or grooves are provided in the side wall of the tubular part or the spacer to link the inner space of the tubular part of the shaft to an outer space of the shaft. When this displacement sensor till- 2005-09-26 10:00 V: \ NOOrganiSatiOn \ HILLFORT IIITERNATIOIIAXA PATEHT_ \ f_NoFamil ',' \ SE \ 2 101 93é6 \ 2 1019356 Appl icationtextfolnstructo: CH 2005-09-lá 1.doc 10 15 20 527 641 5 is suitable as a differential oil pressure sensor or a hydraulic valve stroke sensor or the like, for example the space in which the movable element moves (ie the outer space of the shaft) is filled with hydraulic fluid, and the oil pressure of this outer space tends to vary widely. The hole or groove that links the outer space to the inner space prevents the differential pressure between the outer space and the inner space from becoming too large even in cases where the pressure of the outer space varies greatly in this way, and as a result, is eliminated. the danger of this pressure pushing the magnetic element out of the shaft or destroying the shaft.

An displacement sensor according to another aspect of the present invention comprises a main body having a magnetic sensing device, and the magnetic field forming device arranged as described above, which is capable of moving relative to the main body, and which provides a magnetic field having an intensity corresponding to displacement in the position of the magnetically sensing device.

Brief Description of the Drawings Fig. 1 is a side view of an embodiment of a displacement sensor using a magnetic field forming apparatus according to the present invention; Fig. 2A is a front view of a spacer seen from the front, and Fig. 2B is a side view along a line A-A in Fig. 2A; Fig. 3A is a side view along a central axis of a structure at a rear end portion of a holder for fixing a permanent magnet, and Fig. 3B is a rear view of the rear end portion of the holder seen from behind; Fig. 4A is a side view showing a modified example of a stopper using a screw, and Fig. 4B is a side view showing a modified example of the stopper using a lid; 2005-09-25 10:00 V: \ No0rganisation \ HILLFORT INTERNATIONAL \ PATENTï_NoFamily \ SE \ 2lQ19366 \ 21019366 ApplicationteztToInstructox CH 2005-09-16 l .dec 10 15 20 25 30 35 527 641 6 Fig 5A to SC are side views showing a modified example of a structure for fixing the axial position of a permanent magnet having a different shape; Fig. 6 is a side view showing a modified example in which the axial position of the permanent magnet is fixed by means of spacers at two locations; and Fig. 7 is a side view showing a modified example in which a composite body combining two permanent magnets and a magnetic material is used as a magnetic field generating source.

Description of Preferred Embodiments Fig. 1 is a side view of an embodiment of a displacement sensor using a magnetic field forming device according to the present invention. In the drawing, components are illustrated with diagonal shading made of magnetic materials. With the exception of a permanent magnet 28, components are sketched in black made of non-magnetic materials (eg non-magnetic stainless steel, plastic, rubber, etc.).

As shown in Fig. 1, a displacement sensor 10 comprises a sensor main body 12 and a rod-shaped magnetism-forming device ("movable plug" hereinafter) 14 which is inserted into the sensor main body 12 to be capable of axial movement. The sensor main body 12 comprises a tubular main body housing 16 having openings at the front and rear ends, and a main body housing 18 which fits on the rear end of the main body housing 16. The main body housing 16 and the main body housing 18 are both made of magnetic material, the outer shell of the sensor main body 12, and has the function of magnetically shielding the interior of the sensor main body 12 from the outside.

A pressure-resistant sleeve 20 is inserted into and fixed to the main body housing 16 from the opening side of the front end. One or more (e.g. two in this embodiment) magnetically sensing devices, e.g. Hall-IC circuits 34A, 34B, are fixed in different positions on the outer surface of the 2005-09-26 10:00 V: \ _No0rganisation \ WILLFORT INTERNATIONAL \ PATENT \ _NoFamilyïSE \ 2l0193¿6 \ 21019366 ApplicationtextToInstructor CH 2005-09-16 Ldol: 10 15 20 25 30 35 527 641 7 pressure-resistant sleeve 20. Output signals from these Hall-IC circuits are output to 34A, 34B the exterior of the sensor main body 12 through a signal cable 37, and is fed into a signal processing circuit not shown in the drawing.

The pressure-resistant sleeve 20 has an opening at its front end, and a movement space 30 for the movable plug 14 which assumes an elongated columnar shape surrounded by the wall of the pressure-resistant sleeve 20, is provided on the inside of the pressure-resistant sleeve 20. A typical application for the displacement sensor 10 is to detect displacement in a hydraulic machine, for example the displacement of a coil moved by differential oil pressure or the stroke of a hydraulic valve. In such an application, the movement space 30 inside the pressure-resistant sleeve 20 is filled with high-pressure hydraulic fluid so that high oil pressure is applied to the wall of the pressure-resistant sleeve 20. The pressure-resistant sleeve 20 is made of a robust non-magnetic material (e.g. non-magnetic). magnetic stainless steel), and therefore has sufficient strength to withstand the high oil pressure from the inner space 30. The movable plug 14 is inserted into the movement space 30 from the opening on the front of the pressure-resistant sleeve 20. The movable plug 14 is arranged in a coaxial position with the movement space 30. The movable plug 14 is capable of being moved within a fixed distance range along a central axis 22. The outer diameter of the part of the movable plug 14 inserted in the pressure-resistant sleeve 20 is slightly smaller than the inner the diameter of the pressure-resistant sleeve 20, and from this a small clearance is secured between the outer surface of the movable plug 14 and the inner surface of the t jerk-resistant sleeve 20, which enables the movable plug 14 to move smoothly. In an application, as described above, for detecting displacement in a hydraulic machine, the gap (movement space 30) between the movable plug 14 and the pressure-resistant sleeve 20 is filled with hydraulic fluid. I 2005-09-25 10:00 Vzï NoOrganisation \ WILLFORT lNššRgATíONAL \ PATENTï_NoFamily \ SE \ 2l019366 \ 21G19366 ApplicationteztToInstructor CH zü - 9- 5 1.doc 10 15 20 25 30 35 527 641 8 The main body of the movable plug 14 is substantially columnar shaft 24 made of non-magnetic material. A screw is formed on a front end portion 25 of the shaft 24 for coupling the movable plug 14 to a blank to be displacement measured, for example a coil of a hydraulic valve or the like. A portion 26 of the rear half of the shaft 24 which is inserted into the pressure-resistant sleeve 20 serves as a holder for fixing the permanent magnet 28. The holder 26 is cylindrical and comprises a side wall 26b surrounding a columnar inner space 26a and a opening 26c at the rear end. The round rod-shaped permanent magnet 28 is housed in the inner space 26a of the holder 26. A plurality of claws 26d are provided on the trailing end edge of the side wall 26b of the holder 26. These claws 26d bend inwardly to close the opening 26c, thereby relating to the trailing end surface of the permanent magnet 28. In other words, the claws 26d serve as a stopper for fixing the permanent magnet 28 within the holder 26 so that the permanent magnet 28 is not moved in the direction of the central axis 22.

In addition, the permanent magnet 28 is fixed in a coaxial position with the holder 26 using a method to be described below.

The permanent magnet 28 is pressed into a mold having a different thickness (outer diameter) according to its position in the direction of the central axis 22. In this embodiment, for example, the permanent magnet 28 is pressed into a spindle shape which is thickest in the central position in the axial direction and tapers towards the two ends. This shape was chosen for the permanent magnet 28 to give a predetermined characteristic (eg linear) of the intensity distribution (in particular the intensity of the magnetic field components detected by the Hall-IC circuits 34A, 34B) of a magnetic field 33 formed by the permanent magnet 28. The inner space 26a of the holder 26 assumes a shape and size which fits the thickest location (the central location in this embodiment) of the permanent magnet 28. Thus, in the thickest central location, the permanent magnet 2005-09-26 10:00 V: \ _ NoOrganisation \ HILLEORT INTEENATIONAL \ PATENT \ _NoFami1y \ SE \ 210193¿6 \ 2l019366 ApplicatiöntextToInstructor CH 2805-09-lá l.doc 10 15 20 25 30 35 527 641 9 28 side wall 26b of the holder 26 tight. An annular spacer 32 is fitted over the narrow rear end portion of the permanent magnet 28. The inner surface of the spacer 32 touches the permanent magnet 28 tightly, and the outer surface of the spacer 32 touches the side wall 26b of the holder 26 tightly. Of this, the permanent magnet 28 is fixed to the holder 26 at its thickest central location and the two rear end locations to which the spacer 32 are attached so that the axial position of the permanent magnet 28 matches the central axis 22 of the holder 26.

By choosing a suitable material for the spacer, it is also possible to relieve voltage applied to the permanent magnet 28.

The inner space 26a of the holder 26 is divided into two regions comprising a region in front of the central part of the permanent magnet 28 and a region behind the central part.

A pressure relief hole 26e which links the front region of the inner space 26a of the holder 26 to the outer space (ie the movement space 30) of the holder 26 is pierced to the side wall 26b of the holder 26 in one or more locations. Further, as shown in Fig. 2, to be described hereinafter, a pressure relief groove 32c is formed which links the rear region of the inner space 26a of the holder 26 to the outer space (movement space 30) of the holder 26 in the spacer 32.

In the aforementioned application for measuring displacement in a hydraulic machine, the outer space (movement space 30) of the holder 26 is filled with high-pressure hydraulic fluid, and in particular in the case of a construction machine or the like, the oil pressure of the hydraulic fluid varies greatly. By the action of the pressure-relieving hole 26e and the pressure-relieving groove 32c, differential pressure between the inner space 26a of the holder 26 and the outer space (movement space 30) can be suppressed even in such a case, and the problems caused when the differentiated pressure becomes too great are prevented. 2U05-O9 ~ 26 10: 00 V: \ _NoOrganisaCiOnWYILLFORT INTERNATIONAMPATENTLNoFamily \ SE \ 210193-¿6 \ 2101ä366 ApplicationteztToInstructox: IH 2005-09-16 Ldef: 10 15 20 25 30 35 527 641 10 By imagining each structure the pressure relief hole 26e or the pressure relief groove 32c is formed, for example, when the oil pressure in the outer space (movement space 30) of the holder 26 becomes extremely high, the hydraulic fluid at this high pressure can pass through the minimal gap between the spacer 32 or the permanent magnet 28 and the side wall 26b of the holder 26, and enter the inner space 26a. When the oil pressure of the outer space (the movement space 30) of the holder 26 subsequently drops, the high oil pressure in the inner space 26a can push the permanent magnet 28 out of the holder 26 or cause the holder 26 to break. Such problems are solved with the pressure relief hole 26e and the pressure relief groove 32c described above.

Fig. 2 shows the assembly of the spacer 32.

Fig. 2A is a front view of the spacer 32 seen from the front and Fig. 2B is a side view along a line A-A in Fig. 2A.

The spacer 32 comprises, as shown in Fig. 2, an inner surface 32a for tightly touching the permanent magnet 28, and an outer surface 32b for tightly touching the side wall 26b of the holder 26. The pressure relief groove 32c is formed in one or more locations in the outer surface 32b.

Fig. 3 shows the structure at the rear end portion of the holder 26 for fixing the permanent magnet 28. Fig. 3A is a side view along the central axis 22 of the structure at the rear end portion of the holder 26, and Fig. 3B is a rear view of the rear end portion of the holder 26 seen from behind.

The four exemplary claws 26d shown in Fig. 3, extending from the edge of the rear end of the holder 26, bend inwardly over the outer shape of the rear end portion of the spacer 32 and the permanent magnet 28, thereby serving as a stopper for fixing the permanent magnet 28. securely so that the permanent magnet 28 is not moved axially. The pressure relief grooves 32c, shown in Fig. 3B, of the spacer 32 are positioned in the spaces between adjacent claws 26d. 2005-09-26 10:00 V: \ _ NoOrganisation \ HILLEORT INTERNATIONAL \ PATENT \ _ fl oFamily \ SE \ 21019366 \ 2l019366 ApplicationteztToInstructor CH 2005-09-1 6 l. dox: 10 15 20 25 30 35 527 641 ll Note that different compositions can be used as the stopper other than the plurality of curved claws 26d separated as shown in Fig. 3. For example, the trailing edge of the holder 26 may be dictated to bend uniformly inwardly over the entire the circumference of the holder 26, thereby serving as a stopper. Alternatively, as shown in Fig. 4A, a screw 40 screwed into the holder 26 may be used as a stopper to fix the permanent magnet 28 and the spacer 32.

Alternatively, as shown in Fig. 4B, a lid 41 placed on the holder 26 may be used as a stopper to fix the permanent magnet 28 and the spacer 32. In addition, additional pressure relief holes may be opened in the side wall 26b of the holder 26 instead of providing pressure relief grooves 32c in the spacer 32.

In addition, a different shape from the spindle shape shown in Fig. 1 can be used for the permanent magnet 28 depending on the desired distribution characteristic of the magnetic field 33. Furthermore, as shown by the examples in Figs. 5A to SC, the structure for fixing the axial position of the permanent magnet 28 (e.g., the position, size, etc. of the spacer 32) is varied according to the shape of the permanent magnet 28.

In addition, in the examples illustrated in Figs. 1 and 5A to 5C, respectively, the permanent magnet 28 touches the side wall 26b of the holder 26 closely at its thickest location, and its axial position is fixed by attaching the spacer 32 to another location. In addition, however, the spacer 32 may be attached in a plurality, for example two, locations on the permanent magnet 28 so that the axial position of the permanent magnet 28 is fixed by the spacers 32 in these two locations. Fig. 6 shows an example thereof. In the modified example shown in Fig. 6, the axial position of the permanent magnet 28 is fixed by two spacers 32A, 32B fitted over the respective two ends of the permanent magnet 28. In this case, the permanent magnet 28 need not itself touch the side wall 26b of the holder 26 directly. In addition, voltage applied 2005-09-26 10:06 V: \ _ NoOrganisation \ WILLFORT INTERNATIONALXPATENT \ _NoFamily \ SE \ 210193á6 \ 21019365 ApplicationteztToInstructor CH 2305-09-16 l.doC lO 15 20 25 30 35 527 641 12 permanent magnet 28 light yet more through the spacers 32A, 32B.

Furthermore, a composite body that combines one or more permanent magnets with a magnetic material can be used as the magnetic field generating source instead of a simple permanent magnet 28. Fig. 7 shows an example thereof. In the modified example shown in Fig. 7, two annular permanent magnets 51A, 51B are fitted over the two end portions of a cylindrical yoke 50 made of magnetic material having high permeability. To make the distribution of magnetic field formed by this composite body of the yoke 50 and the permanent magnets 51A, 51B linear, the yoke 50 assumes an outer shape whereby its outer diameter is largest at the two end portions and tapers towards the center. The axial position of this composite body is also fixed by the two spacers 32A, 32B fitted over the respective two locations at the two ends.

An embodiment and several modified examples of the present invention were described above. In all these cases, the operation is performed during assembly to mount the permanent magnet 28 (or the composite body of the yoke 50 and the permanent magnets 51) in the shaft 24 of the movable plug 14 lighter and faster than those of the prior art. More specifically, by means of a simple operation to fit the single spacer 32 (or multiple spacers) over the permanent magnet 28 (or the composite body of the yoke 50 and the permanent magnets 51), insert the permanent magnet 28 into the inner space 26a of the the holder 26 from the opening 26c in the rear end of the holder 26, and forming a stopper at the opening 26c, the permanent magnet 28 (or the composite body of the yoke 50 and the permanent magnets 51) being fixed in themselves in a predetermined position which is coaxial with the holder 26.

The embodiment and the modified examples described above are only examples used to describe the present invention, and the scope of the present invention is no. \ 21019366 ApplicationtextToInstructor CH 2005-09-21. á l. doc 527 641 13 finning shall not be limited solely to this embodiment. The present invention can be implemented according to several other modes without departing from the spirit thereof. 2005-09-Zš 10:00 V: \ No0rganisation \ WILLFORT I¶TERNATIONAL \ PATENT \ _HoFamily \ SB \ 210193¿6 \ 21019366 AppíicationteztToInstructor CH 2005-09-16 l .dot

Claims (5)

10 15 20 25 30 35 527 641 14 PATENT REQUIREMENTS A magnetic field forming apparatus for providing a magnetic field in an outer space, comprising: a shaft having a tubular portion having a side wall surrounding a columnar inner space, and an opening provided at one end of the tubular portion; a rod-shaped magnetic element for generating the magnetic field, which is inserted into the inner space of the tubular part of the shaft and fixed to the tubular part; and an annular spacer disposed over the magnetic member and securely attached to the side wall of the tubular member, thereby fixing a central axis of the magnetic member in a predetermined position within the tubular member. A magnetic field forming device according to claim 1, comprising a stopper in the vicinity of the opening in the tubular part for fixing the magnetic element within the tubular part so that the magnetic element does not move in the direction of the central axis. A magnetic field forming device according to claim 1, wherein a hole or groove for linking the inner space of the tubular part of the shaft to an outer space of the shaft is provided in the side wall of the tubular part or the spacer. A magnetic field forming device according to claim 1, wherein the spacer is arranged in the vicinity of the opening in the tubular part, a hole or a groove for linking the inner space of the tubular part of the shaft to an outer space of the shaft is provided in the spacer, and a stopper is provided near the opening in a position which does not block the hole or groove, for fixing the magnetic element within the tubular 2005-09-26 10:00 V: \ _ NoOrganisation \ HILLFOET INTBRNATIONAL \ PATE§T \ _ fl oFamily \ SE \ 2l01936ö \ 2101936ä ApplicatextToInstructor CH 2005-09-15 Ldor: 10 15 20 527 641 15 part so that the magnetic element does not move in the direction of the central axis. Displacement sensor comprising a main body having a magnetic sensing device, and a magnetic field forming device capable of moving relative to the main body and providing a magnetic field with an intensity corresponding to displacement in a position of the magnetic sensing device. , the magnetic field forming device comprising: a shaft having a tubular portion having a side wall surrounding a columnar inner space, and an opening provided at one end of the tubular portion; a rod-shaped magnetic element for generating the magnetic field, which is inserted into the inner space of the tubular part of the shaft and fixed to the tubular part; and an annular spacer disposed disposed over the magnetic member and securely attached to the side wall of the tubular member, thereby fixing a central axis of the magnetic member in a predetermined position within the tubular member. 2U05 ~ 09-26 10:06 V: \ _ fl oOrganisation \ WILLïORT INTBRNATIONAL \ PATENT \ _NoFami1y \ SE \ 21019366 \ 21019366 App! IcaticnteztToInstructor CH 2005-09-16 1.doc