JPH02104995A - Protector for compressor - Google Patents

Abstract

PURPOSE:To keep off any damage to a compressor due to nonconformity in a refrigerating cycle by installing a pressure switch, detecting refrigerant pressure in the compressor, in conjunction with an electromagnetic sensor part which generates a pulse signal in a detected element with rotation of a drive circuit of the compressor and detects its rotational frequency. CONSTITUTION:A detector 1 of a protector for a compressor is provided with a movable rotation detector 2 held by an elastic bellows 3. This rotation detector 2 has a permanent magnet 201, a rotation detecting coil 203 and an iron core 204, and a movable pin 4 is set up in the center. A reversing plate 6 at the bellows side and a low pressure detecting spring 5 at the opposite side press a movable piece 502. The detector 1 is adjacently attached to a high pressure chamber of the compressor, detecting a detected element of a compressor shaft and generating a pulse. On the other hand, a switch of an electromagnetic clutch comes to OFF by pushing force at time of nonpressure in the high pressure chamber and to ON by pushing force of the bellows 3 at time of normal pressure respectively. At time of abnormally high pressure, the reversing plate 6 pushes the pin 4 upward and the switch is turned off. Thus, the compressor is protected from this abnormally high pressure in a refrigerating cycle and a gas non-sealing state.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a compressor protection device, and particularly to a compressor protection device suitable for detecting an abnormality in a compressor for a car air conditioner.

[Conventional technology]

A conventional compressor protection device is disclosed in Japanese Patent Application Laid-Open No. 56-167887.
As described in the above issue, a detected part is provided on the circumferential surface of the end of the drive shaft of the compressor, and a housing made of a non-magnetic material that adjacently surrounds the end of the load drive shaft is placed opposite to the detected part. An electromagnetic sensor is installed that generates a pulse signal in response to changes in magnetic flux density caused by periodic motion of the detected part due to rotation of the shaft. According to the comparison, if either the drive belt or the electromagnetic clutch develops a problem, the power to the electromagnetic clutch is cut off.

[Problem to be solved by the invention]

The conventional device described above detects when an abnormality occurs in the compressor parts and the driving torque becomes abnormally large, as a change in the rotation speed, and cuts off the power to the compressor. No consideration was given to detecting the cause of abnormality in the parts of the machine, and there was a problem that the compressor could be damaged secondary to damage or malfunction of the refrigeration cycle parts.

An object of the present invention is to provide a compressor protection device that can prevent damage to other parts when the compressor is damaged, as well as prevent damage to the compressor itself due to malfunctions in the refrigeration cycle. .

[Means to solve the problem]

The above object is to provide the detector with an electromagnetic sensor section that generates a pulse signal in response to changes in magnetic flux density caused by periodic motion of the detected section due to rotation of the drive shaft and detects the rotation speed of the drive shaft; This is achieved by incorporating a pressure switch section that cooperates with this electromagnetic sensor section to detect the refrigerant pressure inside the compressor.

Preferably, in the detector, the electromagnetic sensor section is held inside the detector body by a bellows formed of an elastic body, and is disposed so as to be movable in a direction perpendicular to the surface of the bellows, and The pressure switch section is configured to be pressed against the bellows by a spring for pressure detection, and a low pressure switch is provided on the side opposite to the bellows of the electromagnetic sensor section. The load due to the spring overcomes the load due to the pressure inside the compressor applied to the bellows, and the electromagnetic sensor section moves to turn off the low pressure switch and cut off power to the electromagnetic clutch of the compressor. There is.

Preferably, the detector further includes a reversing plate disposed between the bellows and the electromagnetic sensor, and a movable pin movable in a direction perpendicular to the reversing plate, and a reversing plate of the movable pin. The pressure switch section is configured by providing a high pressure switch on the side, and when the inside of the compressor reaches a set high pressure or higher, the reversing plate is reversed and the movable pin is pushed up to turn off the high pressure switch,
It is designed to cut off power to the compressor's electromagnetic clutch.

The detector is preferably arranged in a high pressure chamber inside the compressor.

The detected portion is formed of a magnetic material in which a plurality of plates extend in the radial direction from the outer periphery of a disc, the magnetic material is fixed to the rear end of the drive shaft, and the detector is attached to the magnetic material. Opposite ends of the drive shaft can be arranged in adjacent surrounding housing parts. Further, the detected portion is formed by providing a plurality of circular holes or long grooves in the axial direction on the outer periphery of the drive shaft, and the detector is disposed in the housing portion in the circumferential direction facing the holes or the long grooves. may be set.

[Effect]

If an abnormality occurs in the compressor and the load increases, causing slippage in the compressor's drive mechanism, the belt and electromagnetic clutch, the electromagnetic sensor section of the detector detects this as a change in rotation speed. , cut off the power to the electromagnetic clutch. This prevents damage to other accessories and belt breakage. If the refrigerant in the refrigeration cycle leaks or if the refrigerant is not sealed, the pressure switch part of the detector detects that the pressure in the refrigeration cycle is low and prevents energization to the electromagnetic clutch of the compressor. do. This prevents the compressor from operating with too little refrigerant, thereby preventing damage to the compressor. Additionally, if the cooling fan motor of the condenser breaks down, the pressure in the refrigeration cycle will become abnormally high, and if liquid refrigerant enters the compressor, the pressure inside the compressor will become abnormally high during liquid compression. In this case, the pressure switch section of the detector detects this and cuts off the power to the electromagnetic clutch of the compressor. This prevents the compressor from being operated under abnormally high load and prevents damage to the compressor.

Further, by incorporating the pressure switch section into the detector in cooperation with the electromagnetic sensor section, the structure of the detector becomes compact.

〔Example〕

An embodiment of the present invention will be described below with reference to FIGS. 1 to 6.

In Figures 1 to 3, a detector 1, which is a main component of a compressor protection device, has an annular detector body 1A, and inside the detector body IA there is a detector body IA formed of an annular resin. The rotation detection body 2 is held by a bellows 3 formed of an elastic member and is disposed so as to be movable in a direction perpendicular to the surface of the bellows 3.

A movable pin 4 that is movable in the axial direction is arranged at the center of the rotation detection body 2. The bellows 3 is fixed to the detector main body IA with a fixing fitting 105, and the inside of the main body is sealed. The rotation detection body 2 includes an annular permanent magnet 201, a rotation detection coil 203 wound around a bobbin 202, and an annular iron core 204 for forming a magnetic path, and constitutes an electromagnetic sensor section. The iron core 204 has a notch in a part, and the lead wire of the rotation detection coil 203 can be connected to the iron core 204.
04, and is electrically connected to rotation detection output conductors 205 and 206 that are integrally fixed to the rotation detection body 2. The rotation detection output conductors 205 and 206 can be used even if the rotation detection body 2 moves in the axial direction.

Rotation detection terminals 101 and 1 fixed to the detector main body IA
They are installed parallel to each other so that they always slide in contact with 02.

A low-pressure pressure detection spring 5 is disposed on the side opposite to the bellows of the rotation detection body 2, and this low-pressure pressure detection spring 5 is supported by a spring holder 501 within the annular space of the detector main body IA.
The movable piece 502 is suppressed. When no external pressure is applied to the bellows 3, the movable piece 502 pushes down the rotation detection body 2 by the pressing force of the low pressure detection spring 5.
The displacement is restrained by contacting the pressure detection terminals 103 and 104 (see FIG. 2). The spring retainer 501 is moved by a detection pressure adjustment screw 503, and by changing the initial deflection amount of the low pressure detection spring 5, the set value of the detection pressure can be adjusted. A semicircular pressure detection conductor 207 is arranged on the upper part of the rotation detection body 2.

In the other space, a half-moon-shaped pressure detection conductor 208 is disposed so as to partially pass over the movable pinch.

Low pressure switch terminals 209 and 211 are fixed to the pressure detection conductors 207 and 208, respectively, at positions facing the pressure detection terminals 103 and 104, and high pressure switch terminals 210 are respectively fixed to the other ends of the pressure detection conductors 207 and 208.
and 212 are fixed so that they are in contact with each other.

A reversing plate 6 is interposed between the bellows 3 and the rotation detection body 2,
The reversing plate 6 is formed of a disc-shaped non-magnetic material, and the movable pin 4 is in contact with the center thereof.

The detector 1 constructed in this way is incorporated into a compressor as shown in FIG. 4, and constitutes a protection device.

FIG. 4 shows an example of a movable vane type rotary compressor. By energizing the electromagnetic clutch 7, rotational force is transmitted from the drive source to the drive shaft, that is, the shaft 8, via a belt (not shown), and the shaft Rotor 801 and rotor 80 press-fitted into
The vane 802 fitted into the first slit rotates integrally along the inner wall of the cylinder 9. Along with this, rotor 8o1
．． Vane 802, cylinder 9 and side plate 901
The compression space surrounded by and 902 undergoes a volume change, and the refrigerant is sucked and compressed.

The rear end of the shaft 8 is a housing 1 made of a non-magnetic material.
1 , the housing 11 defines a high pressure chamber 12 . A rotary plate 1o is fixed to the rear end of the shaft 8, and the rotary plate 10 is made of a magnetic material and has three detected portions 10a extending in the radial direction from the outer periphery of the disk. A detector main body IA is fixed to a housing 11 made of a non-magnetic material by a snap ring lla at a position facing the detected part 10a, and an O-ring llb maintains airtightness between the high pressure chamber 12 of the compressor and the outside. ing.

Next, the operation of this embodiment will be further explained with reference to FIGS. 5 and 6.

As the shaft 8 of the compressor rotates, the detected part 10a passes through the front surface of the rotation detection body 2 of the detector 1, so the magnetic flux density of the magnetic path S generated by the permanent magnet 201 changes, and the rotation detection coil 203 The induced voltage generated at the rotation detection terminal 10
1 and 102 as pulse signals. Thereby, the rotation detector 2 detects the rotation speed of the compressor. If an abnormality occurs in the compressor and the load increases, causing the belt and electromagnetic clutch 77 to sag, there is a difference between the rotation speed of the compressor and the rotation speed of the drive source detected by the rotation detector 2. By cutting off the power to the electromagnetic clutch 7, it is possible to prevent damage to other auxiliary machinery and breakage of the belt.

If the refrigerant leaks or is not sealed, the pressure in the high pressure chamber 12 is lower than the set pressure of the low pressure detection spring 5, so as shown in FIG. Pressure switch terminals 209 and 211 are separated. Therefore, conduction between the pressure detection terminals 103 and 104 is cut off, and even if the air conditioner switch is turned on, power to the electromagnetic clutch 7 is cut off, thereby preventing damage to the compressor due to insufficient refrigerant operation or the like.

When the refrigerant is properly sealed, as shown in Figure 5,
Since the pressure in the high pressure chamber 12 is higher than the set pressure of the low pressure detection spring 5, the pressure applied to the bellows 3 pushes up the rotation detection body 2 and the movable piece 502, the low pressure detection spring 5 contracts, and the pressure detection terminal 103 and 104 and the low pressure switch terminals 209 and 211, the pressure detection conductor 207 is connected between the pressure detection terminals 103 and 104.
208 and the high pressure switch terminals 210 and 212, and when the air conditioner switch is turned on, the electromagnetic clutch 7 is energized and the compressor is driven.

If the cooling fan motor of the condenser malfunctions or if liquid refrigerant enters the compressor and is compressed, the high pressure chamber 12 becomes abnormally high pressure, and the pressure applied to the bellows 3 is applied to the reversing plate 6 as shown in FIG. When the set pressure is exceeded, the reversing plate 6 is reversed and the movable pin 4 is pushed up, so that the pressure detection conductor 2
08 is also pushed up and the high pressure switch terminals 210 and 21
2 is disconnected, the conduction between the pressure detection terminals 103 and 104 is cut off, and the power to the electromagnetic clutch is cut off.

As a result, the compressor is not operated under abnormally high load, and damage to the compressor can be prevented.

As described above, according to this embodiment, the rotation detection unit 2 detects the rotation speed of the compressor, the low pressure switch detects that the pressure inside the compressor is low, and the pressure inside the compressor is high pressure. The compressor has a built-in detector that integrates the three functions of a high-pressure switch that detects the presence of a compressor, so it has a compact configuration and prevents damage to other parts if the compressor is damaged. At the same time, damage to the compressor itself due to malfunction of the refrigeration cycle can be prevented.

Another embodiment of the present invention will be described with reference to FIG.

In this embodiment, the type of compressor is different from that in the first embodiment. That is, in the compressor of this embodiment, the rotor shaft 1
3, a rotational force is applied to the vane 14 fitted into the slit of the rotor shaft 1-13. This rotary compressor has a structure in which displacement in the radial direction is restrained, and as the shaft 12 rotates, the tip of the vane 149 traces the same trajectory as the inner circumferential profile of the cylinder 15 to suction and compress refrigerant.

The rotor shaft 13 is provided with detection portions 13a, which are grooves long in the axial direction, at three locations in the center of the shaft.

The detector 1 is disposed at a position facing the outer periphery of the detected portion 13a. The detector 1 is fixed to a front housing 16, which is a circumferential housing portion made of a non-magnetic material, by a snap ring 16a, and airtightness between the inside and outside of the compressor is maintained by an O-ring 16b.

In this embodiment, the detector 1 operates in the same manner as in the first embodiment, and prevents damage to other parts when the compressor is damaged, as well as prevents damage to the compressor itself due to a malfunction in the refrigeration cycle. be able to.

〔Effect of the invention〕

According to the present invention, there is provided a very compact compressor protection device that can prevent harmful effects on other parts when the compressor is damaged, as well as prevent damage to the compressor itself due to malfunctions in the refrigeration cycle. can be provided.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal sectional view of a detector in a compressor protection device according to an embodiment of the present invention, FIG. 2 is a longitudinal sectional view of the same detector as seen from different sections, and FIG. FIG. 4 is a plan view of the detector, and sectional views taken along lines I-1 and II-II in FIG. 3 are the above-mentioned FIG. FIG. 5 is a sectional view of the detector in a different operating state from that shown in FIG. 7 is a sectional view similar to FIG. 2 of the detector in a different operating state from that shown, and FIG. 7 is a longitudinal sectional view of a compressor equipped with a protection device according to another embodiment of the invention; be. 1...Detector, IA...Detector body, 2...Rotation detection body (electromagnetic sensor part), 3...Bellows, 4...Movable pin, 5...Low pressure detection spring, 6 ...reversal board,
7... Electromagnetic clutch, 8... Shaft (immediate acting shaft), 1
0a...Detected part, 11...Housing, 12...
・High pressure chamber, 16...Front housing, 209,2
11...Low pressure switch terminal, 210.212...
・High-pressure casing 1st port 2nd port 3rd Figure ■-=-1st, 5th figure'°3, 6th

Claims (6)

[Claims] 1. A compressor protection device that compresses refrigerant through rotation of a drive shaft, and in which at least one of the housing portion adjacent to and surrounding the end of the drive shaft or the housing portion in the circumferential direction is formed of a non-magnetic material, A detected part that rotates integrally with the drive shaft is provided, a detector is disposed in a housing portion made of a non-magnetic material facing the detected part, and the detector is provided with a detection part that rotates integrally with the drive shaft. An electromagnetic sensor section is provided that detects the rotation speed of the drive shaft by generating a pulse signal in response to changes in magnetic flux density caused by periodic motion of the detection section. A compressor protection device characterized by having a built-in pressure switch section that detects pressure. 2. The detector holds the electromagnetic sensor section inside the detector body by a bellows formed of an elastic body, is disposed so as to be movable in a direction perpendicular to the surface of the bellows, and has a spring for pressure detection. The pressure switch part is configured to be pressed against the bellows by a pressure switch, and a low pressure switch is provided on the side opposite to the bellows of the electromagnetic sensor part,
When the pressure inside the compressor falls below the set low pressure, the load from the spring overcomes the load due to the pressure inside the compressor that is applied to the bellows, and the electromagnetic sensor section moves to turn off the low pressure switch and turn off the compressor. 2. The compressor protection device according to claim 1, further comprising the step of cutting off power to the electromagnetic clutch. 3. The detector further includes a reversing plate disposed between the bellows and the electromagnetic sensor, a movable pin movable in a direction perpendicular to the reversing plate, and a high pressure applied to the reversing plate side of the movable pin. The pressure switch section is configured by providing a switch, and when the inside of the compressor reaches a set high pressure or higher, the reversing plate is reversed, the movable pin is pushed up, and the high pressure switch is turned off, and the compressor's electromagnetic 3. The compressor protection device according to claim 2, wherein the clutch is cut off from being energized. 4. 4. The compressor protection device according to claim 1, wherein the detector is disposed in a high pressure chamber inside the compressor. 5. The detected portion is formed of a magnetic material in which a plurality of plates extend in the radial direction from the outer periphery of a disc, the magnetic material is fixed to the rear end of the drive shaft, and the detector is attached to the magnetic material. The compressor protection device according to any one of claims 1 to 4, characterized in that the compressor protection device is disposed in housing portions that adjacently surround opposing ends of the drive shaft. 6. The detected portion is formed by providing a plurality of circular holes or long grooves in the axial direction on the outer periphery of the drive shaft, and the detector is disposed in the housing portion in the circumferential direction opposite to the holes or the long grooves. The compressor protection device according to any one of claims 1 to 4, characterized in that: