KR20180101175A - Compressor detection device and compressor comprising the same - Google Patents

Abstract

According to one embodiment, a compressor sensing device includes: a housing mounted in a case of a compressor; A hall sensor mounted on the housing for sensing a strength of a magnetic field varying with rotation of the magnetized rotating body of the compressor; And a magnetic pole piece for accumulating the magnetic field around the Hall sensor.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a compressor sensing apparatus and a compressor including the compressor sensing apparatus.

The following description relates to a compressor sensing device and a compressor incorporating it.

Generally, an automobile is provided with an air conditioner (A / C) for cooling and heating the room. Such an air conditioner includes a compressor that compresses gaseous low-temperature and high-pressure gaseous refrigerant introduced from an evaporator into gaseous refrigerant of high temperature and high pressure and sends it to a condenser.

The compressor includes a reciprocating type compressing the refrigerant according to the reciprocating movement of the piston, and a rotary type compressing while rotating. In the reciprocating type, there are a crank type which uses a crank according to a transmission method of a drive source and a crank type which transmits the same to a plurality of pistons, a swash plate type which transmits a swash plate with a swash plate type rotary shaft, a vane rotary type using a rotary shaft, There are scrolling expressions using orbiting scroll and fixed scroll.

Such a compressor typically includes a rotating shaft for transmitting rotational force to a compressor means for compressing the refrigerant.

More specifically, referring to Japanese Patent Publication No. 2715544, a conventional compressor includes a case, compression mechanisms (11, 13) provided inside the case and compressing a refrigerant, a driving source provided outside the case A rotating shaft 4 for transmitting a rotational force from the engine 1 to the compression mechanism 11 and 13 and a clutch for selectively connecting and disconnecting the driving source and the rotating shaft 4.

The clutch includes a pulley (not shown) rotated by receiving power from the driving source, a disc hub assembly (not shown) coupled to the rotating shaft 4 and selectively contacting and spaced from the pulley, A field coil assembly 9 for contacting the pulley with the disc hub assembly 9 and a spacing means for separating the pulley from the disc hub assembly when the field coil assembly 9 is powered off and the field coil assembly is demagnetized, (Not shown).

Here, when the disc hub assembly and the pulley are brought into contact with each other in a state where the rotational speed of the disc hub assembly is different from the rotational speed of the pulley, a slip is generated between the disc hub assembly and the pulley, , Damage to at least one of the belt connecting the driving source and the pulley, the driving source, and the compressor may be caused by an impact force due to contact between the disk hub assembly and the pulley. In consideration of this, a conventional compressor includes a compressor sensing device including a permanent magnet 17 mounted to rotate together with the rotation shaft and a sensor 18 measuring a magnetic flux change of the permanent magnet 17, The rotational speed of the rotating shaft 4 is measured.

However, in this conventional compressor, the compressor sensing device includes the permanent magnet 17. As a result, the inertia of the rotating body is increased, the balance of the rotating body is unstable, noise and vibration are deteriorated, and the bearing supporting the rotating body is damaged. In addition, when the permanent magnet is rotated, the size of the compressor must be increased to prevent the permanent magnet from colliding with other parts, and the weight and cost of the compressor are deteriorated due to the increase of the size of the permanent magnet and the size of the compressor.

Further, since the sensor 18 of the compressor sensing device is installed through the case, there is a problem that the refrigerant leaks through the through-hole of the case for sensor installation.

The background art described above is possessed or acquired by the inventor in the derivation process of the present invention, and can not be said to be a known art disclosed in general public before application of the present invention.

It is an object of one embodiment to provide a compressor sensing device capable of measuring the rotational speed of a rotor without detecting a permanent magnet or detecting whether the compressor is locked or not.

It is also an object of one embodiment to integrate a magnetic field through a pole-piece to effectively detect the displacement of the magnetic flux even when the strength of the magnetic field generated by the electromagnetic clutch is small or the distance between the rotor and the Hall sensor is long. And a compressor sensing device.

According to an embodiment of the present invention, there is provided a compressor sensing apparatus including: a housing mounted to a case of the compressor such that the compressor sensing unit is exposed to the outside of the compressor and not exposed to the inside of the compressor; A Hall sensor mounted on the housing and sensing the intensity of a magnetic field varying with rotation of the magnetized rotor of the compressor; And a pole piece disposed on the opposite side of the rotor of the compressor with respect to the hall sensor.

The Hall sensor can sense the intensity of a magnetic field that changes according to the rotation of the rotor.

The magnetic pole piece may deflect the magnetic field toward the rotor with reference to the hall sensor.

According to an embodiment of the present invention, a compressor sensing apparatus includes a case, a rotor rotatable inside the case, a compressor including a coil for generating an electromagnetic force when the power is applied to magnetize the rotor, A hall sensor for measuring a rotation speed of the rotor by sensing a strength of a magnetic field varying with rotation; And a magnetic pole piece for deflecting the magnetic field toward the rotor side.

The compressor sensing device may further include a housing which supports the hall sensor and the magnetic pole piece, and at least a part of the housing is inserted into the upper portion of the case.

The compressor sensing device may further include a housing supporting the hall sensor and the pole piece and at least a part of which is inserted into a side of the case, the hall sensor being disposed closer to the rotor than the clutch of the compressor The case may have a sensor mounting groove on which the hall sensor is mounted, and the sensor mounting groove may be formed on an outer surface of the case.

Each of the hall sensor and the pole piece may be mounted to the housing in a direction perpendicular to the longitudinal direction of the housing, and the hall sensor may be disposed between the pole piece and the housing.

At least a portion of the compressor sensing device may be inserted into the upper portion of the case, and the hall sensor may be disposed between the clutch and the rotor.

At least a part of the housing is inserted into the side of the case, and the hall sensor can face the rotor.

The Hall sensor is interposed between the clutch and the rotor and may be disposed closer to the rotor than the clutch.

The case may include a sensor mounting groove on which the hall sensor is mounted, and the sensor mounting groove may be formed on an outer surface of the case.

The sensor mounting groove may be formed so as to communicate with the outside of the case and to be shielded from the inside of the case.

According to one embodiment, a compressor includes: a housing mounted in a case of a compressor; A hall sensor mounted on the housing for sensing a strength of a magnetic field varying with rotation of the magnetized rotating body of the compressor; And a stimulus piece disposed on the opposite side of the rotor of the compressor with respect to the hall sensor.

According to one embodiment, the compressor sensing device can measure the rotational speed of the rotor or detect whether the compressor is locked without including a permanent magnet. Thus, increase in inertia of the rotating body and destabilization of the balance are prevented, noise and vibration deterioration can be prevented, and damage to the bearing supporting the rotating body can be prevented. In addition, it is possible to prevent the size, weight, and cost of the compressor according to the permanent magnet from deteriorating. Further, the compressor sensing device is mounted in a groove formed in the outer surface of the case, so that refrigerant leakage can be prevented.

Further, according to one embodiment, the compressor sensing device accumulates the magnetic field generated by the rotor through the magnetic pole piece, effectively reducing the displacement of the magnetic flux even when the intensity of the magnetic field generated by the clutch is small or the distance of the rotor and hall sensor is long. Can be detected.

1 is a cross-sectional view of a compressor according to an embodiment.
FIG. 2 is a view showing a magnetization part and a magnetic force line when power is applied to a coil in the compressor of FIG. 1. FIG.
3 is a cross-sectional view of a compressor sensing apparatus according to an embodiment.
4 is an exploded perspective view of a compressor sensing apparatus according to an embodiment.
5 is a cross-sectional view of a compressor according to one embodiment.
6 is a cross-sectional view of a compressor sensing apparatus according to an embodiment.
7 is an exploded perspective view of a compressor sensing apparatus according to an embodiment.

This patent application is based on and claims the benefit of priority from U.S. Patent Application No. 10-2017-0027026, filed March 2, 2017, the entire contents of which are incorporated herein by reference.

Hereinafter, embodiments will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments, detailed description of known functions and configurations incorporated herein will be omitted when it may make the best of an understanding clear.

In describing the components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

The components included in any one embodiment and the components including common functions will be described using the same names in other embodiments. Unless otherwise stated, the description of any one embodiment may be applied to other embodiments, and a detailed description thereof will be omitted in the overlapping scope.

FIG. 1 is a cross-sectional view illustrating a compressor according to an embodiment, FIG. 2 is a view showing a magnetization part and a magnetic force line when a power is applied to a coil in the compressor of FIG. 1, and FIG. 3 is a cross- And FIG. 4 is an exploded perspective view of a compressor sensing apparatus according to an embodiment. In FIG. 4, the outer housing 52 is omitted for convenience of explanation.

1 to 4, a compressor according to an embodiment includes a case 1, a compression mechanism 2 provided inside the case 1 for compressing the refrigerant, A rotary shaft 3 for transmitting a rotational force from a drive source (not shown) to the compression mechanism 2; a clutch 4 and a compressor sensing device 5 for selectively connecting and disconnecting a drive source (not shown) and the rotary shaft 3; .

The compression mechanism 2 may be formed in various ways such as a swash plate type including a swash plate and a piston, and a scroll type including a revolving scroll and a non-orbiting scroll. 1, a compression mechanism 2 according to one embodiment formed in a swash plate type includes a piston 21 provided so as to be reciprocatable in a bore, a piston 21 fastened to the rotary shaft 3, A swash plate 22 which is rotated and reciprocates the piston 21 and a slope adjusting mechanism 23 which adjusts the compression capacity by adjusting the inclination angle of the swash plate 22 with respect to the rotating shaft 3. [ The inclination adjusting mechanism 23 may include a rotor 232 coupled to the rotating shaft 3 and rotated together with the rotating shaft 3. [

One end of the rotary shaft 3 is connected to the compression mechanism 2 and the other end of the rotary shaft 3 protrudes through the case 1 to the outside of the case 1 and is engaged with the disk hub assembly 42 of the clutch 4 .

The clutch 4 includes a pulley 41 that is rotated by receiving power from a driving source (not shown), a disk hub assembly 42 that is engaged with the rotating shaft 3 and selectively in contact with and spaced from the pulley 41, The field coil assembly 43 and the field coil assembly 43 that are brought into contact with the pulley 41 and the disc hub assembly 42 are turned off and the field coil assembly 43 is demagnetized. 41) and spacing means (not shown) for separating the disk hub assembly 42 from each other.

The pulley 41 has a substantially annular shape and the outer peripheral surface of the pulley 41 is provided with a drive belt (not shown) provided with a drive belt (not shown) for transmitting a drive force from a drive source (not shown) A bearing 44 for rotatably supporting the pulley 41 may be interposed between the inner peripheral surface of the pulley and the outer surface of the case 1. [

A friction surface 415 is formed on one side surface of the pulley 41 to contact the disk 424 of the disk hub assembly 42. A field coil assembly 43 is mounted on the other side surface of the pulley 41 The field coil assembly receiving groove 413 may be formed.

The disk hub assembly 42 may include a hub 422 that is coupled to the rotating shaft 3 and a disk 424 that extends from the hub 422 and selectively contacts and separates the pulley 41.

The field coil assembly 43 may include a coil 434 accommodated in the coil housing 432 and the coil housing 432 and magnetizing the rotor 232 by generating an electromagnetic force when the power is applied.

The spacing means (not shown) may be formed of an elastic member that forces the disc hub assembly 42 in a direction away from the pulley 41.

The compressor according to this embodiment according to this configuration can be operated as follows.

The pulley 41 can be rotated by receiving a driving force from a driving source (not shown). The disk hub assembly 42 is moved toward the pulley 41 by the suction force of the magnetic induction of the coil 434 and can be brought into close contact with the pulley 41 when the coil 434 is powered. That is, the power of the driving source (not shown) can be transmitted to the rotary shaft 3 through the pulley 41 and the disk hub assembly 42 by coupling the disk hub assembly 42 and the pulley 41. Then, the rotary shaft 3 can compress the refrigerant by operating the compression mechanism 2 with the transmitted power.

When the power supply to the coil 434 is stopped, the suction force by the magnetic induction of the coil 434 is not further generated, and the disk hub assembly 42 is separated from the pulley 41 by the separating means (not shown) And may be moved away from the pulley 41 and separated from the pulley 41. That is, power transmission from the drive source (not shown) to the rotary shaft 3 can be interrupted. Then, the compression mechanism (2) is stopped, and the refrigerant compression can be stopped.

In this process, when the disk hub assembly 42 and the pulley 41 come into contact with each other while the rotational speed of the disk hub assembly 42 is different from the rotational speed of the pulley 41, the disk hub assembly 42 and the pulley 41 A drive source (not shown), and a compressor (not shown) are driven by an impact force caused by contact between the disk hub assembly 42 and the pulley 41, May be damaged.

To prevent this problem, the compressor sensing device 5 can measure the rotational speed of a component, for example a rotor 232, which is rotated together with the rotating shaft 3 and / or the rotating shaft 3. [ As a result of the study, the components (for example, the rotor 232 described later) rotated together with the rotary shaft 3 and the rotary shaft 3 when the clutch 4 is magnetized are also magnetized Red region) was identified. The compressor sensing device 5 may be configured to measure the rotational speed of the rotary shaft 3 without including a permanent magnet. The compressor sensing device 5 may include a housing 50, a Hall sensor 53 and a pole-piece 54, a connection line 58 and a connector 59.

The hall sensor 53 can sense a magnetic flux change caused by a change in magnetic flux caused by the rotary shaft 3 to be magnetized or a rotation of a component rotated together with the rotary shaft 3. [ The rotating shaft 3 and the components rotated together with the rotating shaft 3 may collectively be referred to as "rotating body ". The hall sensor 53 can sense a magnetic flux change generated by the rotation of the rotor 232, in particular, of the rotor. Thus, the Hall sensor 53 can measure the rotational speed of the rotor 232. [ For example, while the rotor 232 is rotating, the hall sensor 53 may sense a change in periodic magnetic flux and determine the rotational speed of the rotor 232 based on the period. For example, the rotor 232 may have a radially projected area rather than a circular shape. For example, a first region (hatched region) relatively close to the center and a second region (non-hatched region) relatively far from the center have different radii. When the rotor 232 rotates, the magnetic flux changes due to the protruded area, and the Hall sensor 53 can detect and measure the magnetic flux.

In addition, the hall sensor 53 can determine whether the compressor is locked by detecting a sudden change in magnetic flux. For example, the hall sensor 53 can confirm that the compressor is locked when a magnetic field is formed and then disappears. Likewise, if the hall sensor 53 has no magnetic field but is newly formed, it can be seen that the compressor is unlocked.

The accuracy of the hall sensor 53 can be improved as it is closer to the object to be measured. The Hall sensor 53 is preferably provided adjacent to the rotary shaft 3 when it is formed so as to measure the magnetic flux change by the rotary shaft 3 and is provided within the range of magnetic force lines formed between the clutch 4 and the rotary shaft 3 May be more preferable. However, since the diameter of the rotary shaft 3 is relatively small, the Hall sensor 53 can be adjacent to the rotary shaft 3 only when it is fixed to the inner space center side of the case 1, It is not easy to fix the sensor 53 and the magnetic force line range formed between the clutch 4 and the rotary shaft 3 is narrow and the hole sensor 53 is located at a position where the accuracy of the hall sensor 53 can be improved It may not be easy to arrange it in the housing.

The Hall sensor 53 can be more adjacent to the rotor 232 when it is formed to measure the change in magnetic flux by the component, particularly the rotor 232, which rotates the Hall sensor 53 together with the rotating shaft 3 Accuracy can be improved.

The Hall sensor 53 is preferably disposed adjacent to the rotor 232 when it is formed so as to measure the magnetic flux change by the rotor 232. The Hall sensor 53 is preferably disposed adjacent to the rotor 232, It may be more preferable to be installed in the inside. In this case, the diameter of the rotor 232 is relatively large, so that even if the Hall sensor 53 is fixed to the case 1, it can be adjacent to the rotor 232 and the gap between the clutch 4 and the rotor 232 It is much easier for the Hall sensor 53 to be disposed at a position where the accuracy of the Hall sensor 53 can be improved. Particularly, if the hall sensor 53 is installed in a region where the magnetization region (red region) as shown in FIG. 2 is overlapped, it is preferable to arrange the Hall sensor 53 in the upper housing of the rotor 232. If the rotor 232 is disposed closer to the clutch 4 than the rotor 232, the hall sensor 53 will measure the magnetization state of the clutch 4, not the rotor 232, It is hard to judge. Therefore, even when the Hall sensor 53 is disposed between the clutch 4 and the rotor 232, it is preferable that the Hall sensor 53 is disposed close to the rotor 232.

The hall sensor 53 is attached to the sensor mounting groove 12 formed in the case 1. The sensor mounting groove 12 may be formed to be engraved from the outer surface of the case 1. [ That is, the sensor mounting groove 12 may be formed so as to communicate with the outside of the case 1 and be shielded from the inside of the case 1. Thus, leakage of the refrigerant by the sensor mounting groove 12 can be prevented. That is, since the sensor mounting groove 12 is formed so as not to penetrate through the case 1, it is possible to prevent the refrigerant from leaking from the inside of the case 1 to the outside through the sensor mounting groove 12.

The Hall sensor 53 may include a sensor body 531 and a sensor terminal 532. The sensor body 531 can sense a change in magnetic flux. The sensor terminal 532 can transmit a voltage change caused by a change in magnetic flux to the outside.

The sensor body 531 may be disposed parallel to the rotor 232. In other words, the area in which the sensor body 531 and the rotor 232 overlap with each other with respect to the direction perpendicular to the upper surface of the rotor 232 may be the maximum. In this case, the number of magnetic force lines passing through the sensor body 531 may be the maximum, and the hall sensor 53 can accurately detect the magnetic flux change.

The magnetic pole piece 54 can accumulate the magnetic field around the hall sensor 53. [ The magnetic field generated from the magnetized rotor 232 can be formed extensively around the rotor 232 where the magnetic pole piece 54 accumulates such magnetic field to increase the density of the magnetic field passing through the Hall sensor 53 . As a result, the hall sensor 53 can more accurately measure the magnetic flux change.

The magnetic pole piece 54 can be disposed closer to the rotor 232 than the clutch 4 and can bias the magnetic field toward the rotor 232 with respect to the Hall sensor 53. [ For example, a magnetic field generated and spreading from the rotor 232 can be deflected by the stimulating piece 54 and accumulated in the space between the rotor 232 and the stimulating piece 54. The magnetic pole piece 54 can separate the magnetic field generated from the rotor 232 and the magnetic field generated from the clutch 4.

The stimulating piece 54 may be disposed on the opposite side of the rotor 232 with respect to the Hall sensor 53. [ In other words, the rotor 232, the Hall sensor 53 and the magnetic pole piece 54 can be arranged in this order. In this case, the magnetic pole piece 54 can accumulate the magnetic field generated by the rotor 232 around the Hall sensor 53. [ For example, the magnetic pole piece 54 can prevent a part of the magnetic field generated by the rotor 232 from escaping out through the hall sensor 53. [ The magnetic pole piece 54 can increase the strength of the magnetic field around the hall sensor 53 and improve the measurement accuracy of the hall sensor 53. [ The magnetic pole piece 54 can also block the magnetic field generated by the clutch 4 from approaching the hall sensor 53. [

On the other hand, when the magnetic pole piece 54 is arranged in the order of the rotor 232, the magnetic pole piece 54 and the hall sensor 53 in the order of receiving the magnetic field first than the Hall sensor 53, A magnetic force line of a uniform shape reaches the Hall sensor 53, and the hall sensor 53 can not detect a change in the magnetic field. That is, according to this arrangement, the hall sensor 53 can not sense the rotation of the rotor 232.

The pole piece 54 may be disposed parallel to the rotor 232. In other words, with respect to the direction perpendicular to the upper surface of the rotor 232, the area where the pole piece 54 and the rotor 232 overlap can be the maximum.

The housing 50 can be mounted on the case 1. [ The housing 50 is exposed to the outside of the compressor and may not be exposed inside the compressor. For example, the housing 50 may be mounted in the sensor mounting groove 12, which is engraved from the outer surface of the case 1. With this structure, even if the housing 50 is mounted on the compressor, refrigerant leakage can be prevented. The housing 50 includes an inner housing 51 for supporting the hall sensor 53 and the magnetic pole piece 54 and an inner housing 51 for covering the inner housing 52 and preventing the sensor 53 and the magnetic pole piece 54 from being separated And may include an outer housing 52.

The inner housing 51 includes a hole sensor mounting portion 511, a magnetic pole mounting portion 512, a magnetic pole fixing portion 513, a housing coupling portion 514, a sensor terminal guide 515, a connection line guide 516, Line mounting portion 517 as shown in FIG.

The Hall sensor mounting portion 511 has a shape corresponding to the sensor body 531 and can prevent the sensor body 531 from vibrating relative to the inner housing 51. [ The magnetic pole attachment portion 512 has a shape corresponding to the magnetic pole piece 54 and can prevent the magnetic pole piece 54 from vibrating relative to the inner housing 51. [ The Hall sensor 53 and the magnetic pole piece 54 can be easily attached to and detached from the inner housing 51. When the compressor is used for a long period of time, the hall sensor 53 and the pole piece 54 may be damaged by vibration. The Hall sensor 53 and the magnetic pole piece 54 can be easily replaced.

The magnetic pole mounting portion 512 may be formed above the hall sensor mounting portion 511. The magnetic pole piece 54 can be mounted on the magnetic pole piece mounting portion 512 after the hall sensor 53 is mounted on the hall sensor mounting portion 511.

The magnetic pole piece 513 can prevent the magnetic pole piece 54 from separating from the inner housing 51. [ The magnetic pole piece fixing portion 513 may be an elastic member protruding from both sides of the magnetic pole piece mounting portion 512. [ As another example, the magnetic pole piece fixing unit 513 is melted with the magnetic pole piece 54 disposed therebetween, so that the magnetic pole piece 54 can be firmly fixed.

Each of the hall sensor 53 and the magnetic pole piece 54 may be mounted on the housing 50 in a direction perpendicular to the longitudinal direction of the housing 50. For example, each of the hall sensor 53 and the pole piece 54 may be mounted on the inner housing 51 in a direction perpendicular to the longitudinal direction of the inner housing 51. [ The Hall sensor 53 may be disposed between the magnetic pole piece 54 and the inner housing 51. In other words, the Hall sensor 53 can be sandwiched between the pole piece 54 and the inner housing 51. The magnetic pole piece 54 may be positioned above the hall sensor 53 in a state where the hall sensor 53 is mounted on the hall sensor mounting portion 511. [ At this time, the left and right sides of the magnetic pole piece 54 can be supported by the magnetic pole piece fixing portion 513. For example, in a state where the stimulating piece 54 is supported by the stimulating piece fixing part 513, the stimulating piece fixing part 513 can be fused. Most of the heat transmitted to the Hall sensor 53 in the melting process can be blocked by the magnetic pole pieces 54. [

The housing coupling portion 514 can fix the outer housing 52. The user can operate the housing engagement portion 514 to separate the outer housing 52 from the inner housing 51 or to couple the outer housing 52 and the inner housing 51 together.

The sensor terminal guide 515 can guide the sensor terminal 532 to be mounted on the inner housing 51 correctly. The sensor terminal guide 515 may be a longitudinal member protruding upward. The sensor terminal guide 515 can maintain the gap between the two sensor terminals 532. [

The connecting line guide 516 can guide the connecting line 58 to be properly mounted on the inner housing 51. The connecting line guide 516 may be a longitudinal member protruding upward. The connection line guide 516 can match the spacing of the two connection lines 58 with the spacing of the two sensor terminals 532.

The connection line mounting portion 517 can support the two connection lines 58, respectively. The width of the connection line mounting portion 517 may be the same as the width of the connection line 58. [

The outer housing 52 can prevent the hole sensor 53, the magnetic pole piece 54, the connecting line 58 and the connector 59 from being separated from the inner housing 51. [

The connection line 58 may be connected to the sensor terminal 532. The connection line 58 may include a connection terminal 581 and a connection line body 582.

The connection terminal 581 may be electrically connected to the sensor terminal 532.

The connection line body 582 may be fixed to the connection line mounting portion 517.

The connector 59 can connect the connection line 58 with an external electronic device.

FIG. 5 is a cross-sectional view illustrating a compressor according to an embodiment, FIG. 6 is a cross-sectional view of a compressor sensing apparatus according to an embodiment, and FIG. 7 is an exploded perspective view of a compressor sensing apparatus according to an embodiment.

5 to 7, a compressor according to an embodiment includes a case 1, a compression mechanism 2, a drive source (not shown), a rotary shaft 3, a clutch 4, and a compressor sensing device 6, . ≪ / RTI >

The compressor sensing device 6 can be disposed radially outward of the rotor 232 when the space between the clutch 4 and the rotor 232 is narrow and installation is not easy. In this case, the installation of the compressor sensing device 6 can be facilitated.

The compressor sensing device 6 may include a housing 60, a hall sensor 63 and a pole piece 64, a connecting line 68 and a connector 69. The housing 60 may include an inner housing 61 and an outer housing 62. The inner housing 61 includes a magnetic pole piece mounting portion 611, a hall sensor mounting portion 612, a magnetic pole piece fixing portion 613, a sensor terminal guide 615, a connection line guide 616 and a connection line mounting portion 617 can do. The hall sensor 63 may include a sensor body 631 and a sensor terminal 632

The sensor body 631 may be disposed side by side with the rotor 232. In other words, the area where the sensor body 631 and the rotor 232 overlap with each other with respect to the direction perpendicular to the side surface of the rotor 232 may be the maximum.

The sensor body 631 may face the rotor 232. The sensor terminal 632 may be folded more than once, for example, and wound around the inner housing 61. The sensor terminal 632 extends upward from the sensor body 631 and then bends in a direction toward the connection line 68 and can bend downward again. Due to the "∩" shape like this, the hall sensor 63 can be stably arranged in the inner housing 61.

The pole piece 64 may be disposed side by side with the rotor 232. In other words, with respect to the direction perpendicular to the side surface of the rotor 232, the area where the pole piece 64 and the rotor 232 overlap may be the maximum.

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. For example, it is contemplated that the techniques described may be performed in a different order than the described methods, and / or that components of the described structures, devices, and the like may be combined or combined in other ways than the described methods, Appropriate results can be achieved even if they are replaced or replaced. Therefore, other implementations, equivalents to other embodiments and the claims are also within the scope of the following claims.

Claims (10)

A housing mounted to the case of the compressor so as to be exposed to the outside of the compressor and not exposed to the inside of the compressor;
A Hall sensor mounted on the housing and sensing the intensity of a magnetic field varying with rotation of the magnetized rotor of the compressor; And
And a pole piece disposed on the opposite side of the rotor of the compressor with respect to the hall sensor.
The method according to claim 1,
Wherein the hall sensor senses an intensity of a magnetic field that changes in accordance with rotation of the rotor.
3. The method of claim 2,
Wherein the magnetic pole piece includes a compressor sensing device for deflecting the magnetic field toward the rotor with respect to the Hall sensor
The method of claim 3,
Each of the hall sensor and the pole piece is mounted to the housing in a direction perpendicular to the longitudinal direction of the housing,
Wherein the Hall sensor is disposed between the pole piece and the housing.
1. A compressor sensing device for sensing a compressor including a case, a rotor rotatable inside the case, and a coil for generating an electromagnetic force when the power is applied to magnetize the rotor,
A hall sensor for measuring the rotational speed of the rotor by sensing the intensity of the magnetic field varying in accordance with the rotation of the magnetized rotor; And
And a magnetic pole piece for deflecting the magnetic field toward the rotor side.
6. The method of claim 5,
Further comprising a housing which supports the hall sensor and the magnetic pole piece, and at least a part of which is inserted into the upper portion of the case.
6. The method of claim 5,
Further comprising a housing which supports the hall sensor and the magnetic pole piece, and at least a part of which is inserted into a side portion of the case.
6. The method of claim 5,
Wherein the hall sensor is disposed closer to the rotor than the clutch of the compressor.
6. The method of claim 5,
Wherein the case has a sensor mounting groove on which the hall sensor is mounted,
Wherein the sensor mounting groove is formed on an outer surface of the case.
A compressor comprising the compressor sensing device according to claim 1.

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