JP2556099B2 - Scroll compressor - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a scroll compressor that compresses a refrigerant gas or the like by engaging a pair of spiral side plates with each other and rotating one of them.

[Conventional technology]

This type of scroll compressor is used in a refrigerating device, a refrigerant compressor of an air conditioner, and the like, and is disclosed in, for example, JP-A-60-2069.
The structure disclosed in Japanese Patent Publication No. 89 etc. is constructed as shown in FIG. That is, at the upper end of the closed container 2 fixed on the foot 1, a fixed scroll 3 integrally formed by a disk-shaped base plate 3a and a spiral side plate 3b protruding from the lower surface thereof (detailed later). Is fixed to the upper bearing frame 4 on the side of the closed container 1 having the oil return hole 4a by a plurality of bolts 5, and the upper bearing frame 4 and the lower bearing frame 6 integrally connected thereto are A main shaft 7 is rotatably supported by an upper main bearing 8 and a lower main bearing 9. Reference numeral 10 denotes a motor / stator which is formed in a cylindrical shape and fixed to the lower bearing frame 6 by a plurality of bolts 11, and whose inner hole is fixed to the main shaft 7 by press fitting, shrink fitting or the like. 12 is fitted, and the main shaft 7 is rotated via the motor rotor 12 by energizing the motor. Reference numeral 13 denotes an oil cap which is fitted into a hole of a cover 15 which covers an oil sump 14 below the closed container 2 and which is fixed by press fitting, shrink fitting or the like at the lower end of the main shaft 7, and the suction port 13a at the lower end thereof is an oil sump. Opened into oil 16 stored in 14.

An eccentric hole 7a having an axis eccentric with respect to the axis of the main shaft 7, that is, the axis of the upper main bearing 8 is formed at the upper end of the main shaft 7. An orbiting scroll shaft 17a indicated by is rotatably supported by an orbiting bearing 18. The orbiting scroll 17 includes a base plate 17b integrally formed with a shaft 17a, and a side plate 3b of the fixed scroll 3 formed in a spiral shape on the upper surface of the base plate 17b.
A side plate 17c that engages with is protrudingly provided. Rocking scroll 1
Item 7 will be described later in detail. A suction port 20 and a discharge port 21 are formed in the outer peripheral portion and the central portion of the crescent-shaped compression chamber 19 formed between the side plates 3b and 17c, respectively.
The discharge port 21 and the discharge port 21 are connected to a device outside the machine via a suction pipe 2a and a discharge pipe 22. 23 is the discharge port 21 at the center of the compression chamber 19.
And 24 is an Oldham coupling which is arranged between the orbiting scroll 17 and the upper bearing frame 4 to regulate the rotation of the orbiting scroll 17, and 25 is a thrust bearing. .

An eccentric portion with respect to the axis of the main shaft 7 is provided with an oil filler hole 26, which is opened at the lower end into the oil cap 13, and penetrates in the axial direction. The oil filler hole 26 communicates with the eccentric hole 7a. The inside of the oil sump 14 and the rocking bearing 18 and the lower main bearing 9 are communicated with each other through the oil hole 27.

FIG. 7 is a cross-sectional view of the compression chamber formed by the engagement of the fixed scroll and the orbiting scroll, and the configuration of both scrolls will be described based on the figure. Between the side plate 3b of the fixed scroll 3 and the side plate 17c of the orbiting scroll 17, a pair of compression chambers 19a, 19b which are symmetrical to each other are formed on the innermost peripheral side, and outside thereof. A pair of compression chambers 19c and 19d that are symmetrical to each other are formed. Further, in the central portion, a discharge chamber 23 communicating with the discharge port 21 and having the same internal pressure P ₀ is formed. The drawing shows a state immediately before the discharge chamber 23 and the compression chambers 19a and 19b communicate with each other.

With the above configuration, when the main shaft 7 is rotated by the driving force generated by the motor-stator 10 and the motor-rotor 12 when the motor is energized, the orbiting scroll is performed.
17 is revolved by the eccentric action while its rotation is restricted by the Oldham coupling 24, and the refrigerant gas sucked from the suction pipe 2a cools the motor rotor 12 and the motor stator 10 and then revolves around the orbiting scroll 17. It is taken into the compression chamber 19 formed between the side plate 17c and the stationary scroll side plate 3b of the fixed scroll 3 from the suction port 20 and compressed.
The compressed refrigerant gas is discharged from the discharge pipe 22 to the outside of the compressor through the discharge chamber 23 and the discharge port 21.

When the main shaft 7 rotates, the oil 16 in the oil sump 14 is supplied to the rocking bearing 18 and the lower main bearing 9 through the suction port 13a of the oil cap 13 and the oil supply hole 26 by the action of centrifugal force, and further shakes. Oil is supplied in order from the dynamic bearing 18 to the upper main bearing 8 and the thrust bearing 23. Oil 16 lubricating each of these bearings 18, 9, 8, 23
Is dropped by gravity and returned to the oil sump 14.

In FIG. 7, the internal pressure of the discharge chamber 23 is P ₀ , the compression chambers 19a, 19
When the internal pressure of b is P ₁ , the internal pressure of the compression chambers 19c and 19d is P ₂ , and the internal pressure of the outermost peripheral side where the compression chamber is not yet formed is P ₃ , P ₀ > P ₁ > P ₂ > P _3, and the discharge chamber 23 and the compression chamber 19
After communication with a and 19b, P ₀ = P ₁ > P ₂ > P ₃ .

[Problems to be Solved by the Invention]

However, in such a conventional scroll compressor, when the liquid refrigerant is started in a state in which a large amount of the liquid refrigerant is laid in the closed container 2 or when a large amount of the liquid refrigerant is sucked at the time of the liquid back, the liquid scroll is in a compressed state. Innermost compression chamber 19a, 19
The pressure P ₁ immediately before the b communicates with the discharge chamber 23 becomes the maximum pressure and may reach 100 to 200 atg in a pulsed manner, and at this time, P ₀ << P ₁ >> P ₂ > P ₃ .

When this happens, the pressure difference between P ₀ and P ₁ and P ₂
The differential pressure with P ₃ becomes abnormally large, and the stress at the roots of both spiral side plates 3b, 17c becomes large, causing deformation or damage, or the fixed scroll 3 with only bolt fastening.
Between the bearing frame 4 and the bearing frame 4, the relative positions of the side plates 3b and 17c of the fixed scroll 3 and the orbiting scroll 17 are displaced, and there is a problem that a locked state or abnormal noise occurs.

The present invention has been made in view of the above points, and an object thereof is to provide a scroll compressor in which the internal pressure does not abnormally increase even during liquid compression.

[Means for solving the problem]

In order to achieve such an object, in the present invention, while fixing the spiral thin plate along the spiral side plate on the upper surface of the base plate of the fixed scroll and the orbiting scroll, at the center of the upper surface of each scroll. A recess for inserting the thin plate that elastically deforms so as to connect at least a pair of compression chambers on the innermost peripheral side of the inter-plate compression chambers with the discharge chamber in the central portion when in a liquid compression state Is provided, and the communication plate is provided on the thin plate of the orbiting scroll so that the pressure in the recess and the pressure in the discharge chamber are the same.

[Work]

When the orbiting scroll revolves eccentrically while the rotation of the main shaft is restricted, the refrigerant gas taken from the suction port into the compression chamber between both spiral side plates is compressed, and passes through the discharge chamber and the discharge port to reach the outside of the compressor. Is discharged to.

When a large amount of liquid refrigerant is sucked into a liquid compression state, the thin plate elastically deforms and retreats into the concave hole, and the compression chamber on the innermost peripheral side where the internal pressure becomes maximum and the discharge chamber of lower pressure than this. Since the cutoff state changes to the communication state, the liquid flows from the compression chamber on the innermost peripheral side into the discharge chamber, and abnormal pressurization can be avoided.

〔Example〕

1 to 5 show an embodiment of a scroll compressor according to the present invention. FIG. 1 (a) is a perspective view of a thin plate, FIG. 1 (b) is a perspective view of an orbiting scroll, and FIG. Is a plan view of an orbiting scroll, FIG. 3 is a perspective view of a fixed scroll, and FIG.
FIG. 5 is an enlarged vertical sectional view of a scroll compressor main part in a normal compression state, and FIG. 5 is an enlarged vertical sectional view of a scroll compressor main part in a liquid compression state. Since the configuration other than the fixed scroll and the orbiting scroll is the same as that of the conventional scroll compressor shown in FIG. 6, the description thereof will be omitted, and FIG. 6 will be used when it is necessary to explain the configuration and operation thereafter. explain. In the figure, the orbiting scroll 17 has a shaft 17 at the center.
a has a base plate 17b integrally formed, and this base plate 17b
A side plate 17c formed in a spiral shape is projected on the upper surface of the. Further, a tip seal 30 for sealing the side plate 17c in the axial direction is attached to the upper end surface of the side plate 17c. 31 is a side plate 1 on a thin disk 31a formed of an elastic steel plate such as spring steel.
7c is a thin plate formed in a spiral shape by providing a slit 31b having the same shape and size as the 7c, and the slit 31b is brought into close contact with the upper surface of the base plate 17b by engaging the side plate 17c. Lifting is restricted by a step portion 17d provided on the inner wall base of the side plate 17c. Reference numeral 31c is a small hole formed in the center of the thin plate 31. Furthermore, on the upper surface of the base plate 17b, a recess 17e for engaging the thin plate 31 when elastically deformed by the internal pressure is provided as the discharge chamber 23 and the compression chamber 1 on the innermost peripheral side.
The discharge chamber 23 and the compression chamber 19b are configured so as to communicate with each other through a gap between the thin plate 31 and the tip seal 30 by this elastic deformation. The shape and depth of the recess 17e are determined by the shape and size of the spiral, the rigidity of the thin plate 31, and the like.

On the other hand, the fixed scroll 3 fixed to the closed container 2 side
Is provided with a base plate 3a having a plurality of mounting holes 3c, and a side plate 3b formed in a spiral shape is projected on the lower surface of the base plate 3a. Further, a chip seal 32 for sealing the side plate 3b in the axial direction is attached to the lower end surface of the side plate 3b. Reference numeral 33 is a thin plate formed in a spiral shape by providing a slit 33b having the same shape and size as the side plate 3b on a thin disk 33a formed of a steel plate having elasticity such as spring steel.
By engaging with b, it is brought into close contact with the lower surface of the base plate 3a along with it, and lifting is restricted by the stepped portion 3d provided on the inner wall base of the side plate 3b. Reference numeral 33d is a through hole formed in the central portion of the thin plate 31 and communicated with the base plate 3a side discharge port 21 having the same diameter and the same diameter as the through hole. Further, on the lower surface of the base plate 3a, a concave portion 3e for engaging the thin plate 33 when elastically deformed by the internal pressure is provided as the discharge chamber 23 and the innermost compression chamber 19a.
The discharge chamber 23 and the compression chamber 19a are configured so as to communicate with each other at a position a, and the elastic chamber allows the discharge chamber 23 and the compression chamber 19a to communicate with each other through a gap between the thin plate 33 and the tip seal 32. Reference numeral 20 is a suction port opened to the outermost compression chamber.
The shape and depth of the recess 3e are determined by the shape size of the spiral, the rigidity of the thin plate 33, and the like.

The orbiting scroll 17 and the fixed scroll 3 thus configured are arranged by engaging the side plate 17c and the side plate 3b, as shown in FIG.
As shown in the figure, a shaft 17a is supported by an eccentric hole 7a of the main shaft 7. Further, the fixed scroll 3 has a base plate 3a fixed to the upper bearing frame 4 on the closed container 2 side. As a result, a discharge chamber 23, which communicates with the discharge port 21 through the through hole 33d, is formed between the side plates 17c and 3b in the central portion, and three pairs of pairs symmetrical to each other are formed on the outside thereof. Compression chambers 19a-19f
Is formed between the side plates 17c and 3b, and the compression chamber 19 on the outermost peripheral side is formed.
A suction port 20 is opened at e and 19f. And the discharge chamber 2
3 and the compression chambers 19a, 19b, and adjacent compression chambers 19a-1
The 9f is sealed by chip seals 30 and 32 so as not to be electrically connected to each other. Other configurations are the same as those of the conventional scroll compressor shown in FIG.

The operation of the scroll compressor configured as above will be described. When the main shaft 7 rotates due to the start of the motor, the oscillating scroll 17 whose shaft 17a is rotatably supported by the eccentric hole 7a is eccentrically revolved with its rotation restricted by the Oldham coupling 24. By this, the refrigerant gas taken into the compression chambers 19e, 19f from the suction port 20 moves to the compression chambers 19c, 19d to 19a, 19b and is compressed, and the discharge chamber 23, the through hole 33d, the discharge port 21 and the discharge pipe. It is discharged to the outside via 22.

In the compression section of the scroll compressor operating in this manner, during normal operation, the discharge chamber 23 and the recesses 3b, 17e are equalized to the pressure P ₀ by the through hole 33d and the small hole 31c, and the discharge chamber 23 is P ₀ ≧ P between pressure P ₀ the compression chamber 19a, the internal pressure P ₁ of 19b of
_Because of the relationship of ₁ , the thin plates 31 and 33 do not deform as shown in FIG.

If the liquid refrigerant starts up with a large amount of it lying down, or if a large amount of liquid refrigerant is sucked from the suction port 20 when the liquid is backed up,
In the liquid compression state, the internal pressure P ₁ of the compression chambers 19a, 19b rises abnormally, but in this case, P ₁ >> P ₀ and the thin plates 31, 33 are elastically deformed as shown in FIG. 17e, 3e is engaged, since the liquid refrigerant in the compression chambers 19a, 19b flows into the discharge chamber 23 through the gap between the thin plates 31, 33 and the tip seals 30, 32,
Abnormal pressurization of the compression chambers 19a, 19b is prevented. After the liquid refrigerant has flowed into the discharge chamber 23, the thin plates 31 and 33 elastically return to normal compression.

In the present embodiment, the recesses 3e, 17e are formed in the compression chamber 19 on the innermost peripheral side.
Although the example is provided only for the parts corresponding to a and 19b, the outer compression chamber 1
You may also provide in the corresponding part of 9c-19f.

〔The invention's effect〕

As is apparent from the above description, according to the present invention, in the scroll compressor, the thin plates along the spiral side plates are fixed to the upper surfaces of the base plates of the fixed scroll and the orbiting scroll, and the central portion of the upper surface of each scroll is fixed. When the liquid compression state is reached, the thin plate elastically deformed is engaged so that at least the pair of compression chambers on the innermost peripheral side of the inter-side plate compression chambers and the discharge chamber at the central portion communicate with each other. The recess is provided and the thin plate of the orbiting scroll is provided with the communication part with the discharge chamber where the pressure of the recess and the pressure of the discharge chamber are the same, so that the recess is always discharged by the communication part with an inexpensive and simple structure. Since the pressure in the chamber is equalized and the recess has the maximum pressure during normal operation, deformation of the thin plate does not occur, and therefore refrigerant does not leak, and compression operation can be performed without lowering efficiency. On the other hand, when the liquid is compressed, the pressure of the innermost compression chamber becomes larger than the pressure of the discharge chamber, that is, the recess,
The thin plate is deformed and refrigerant leaks from the innermost peripheral compression chamber to the discharge chamber, which can prevent abnormal pressurization and accompanying deformation and damage of the compressor.Moreover, the refrigerant leaks to the discharge side. It has a special effect that the decrease can be made small.

[Brief description of drawings]

1 to 5 show an embodiment of a scroll compressor according to the present invention. FIG. 1 (a) is a perspective view of a thin plate, FIG. 1 (b) is a perspective view of an orbiting scroll, and FIG. Is a plan view of an orbiting scroll, FIG. 3 is a perspective view of a fixed scroll, and FIG.
The figure shows an enlarged vertical cross-sectional view of the main part of the scroll compressor shown in a normal compression state, Fig. 5 shows an enlarged vertical cross-sectional view of the main part of the scroll compressor shown in a liquid compression state, and Fig. 6 shows a vertical section of a conventional scroll compressor. A plan view and FIG. 7 are sectional views of a compression chamber and a discharge chamber which are also formed by a fixed scroll and an orbiting scroll. 3 ... Fixed scroll, 3a, 17b ... Base plate, 3b, 17c ... Side plate, 3e, 17e ... Recessed portion, 19a-19f ... Compression chamber, 20 ... Suction hole, 21 ... Discharge port, 23 ... … Discharge chamber, 31,33 …… thin plate.

 ─────────────────────────────────────────────────── ───Continued from the front page (56) References JP-A-58-51289 (JP, A) Actually opened 60-77786 (JP, U) Actually opened 59-75592 (JP, U) Actually opened 56- 147386 (JP, U) Actually opened 57-136891 (JP, U)

Claims (1)

(57) [Claims] Claim: What is claimed is: 1. A fixed scroll composed of a base plate and a spiral side plate projecting from the base plate and side plates of an orbiting scroll are engaged with each other to rotate the orbiting scroll, whereby the space between the both side plates is rotated. In a scroll compressor configured to compress the fluid taken in from the suction port of the outer peripheral portion of the side plate into the compression chamber and discharge the fluid from the discharge port via the discharge chamber of the central part, along the side plate on the upper surface of the base plate of each scroll. In addition to fixing the spiral thin plate, at the center of the upper surface of each scroll, when in a liquid compression state, at least the innermost pair of compression chambers of the compression chambers and the discharge chamber are provided. A recess for inserting the elastically deformable thin plate is provided, and the thin plate of the orbiting scroll is provided with a communicating portion with the discharge chamber for making the pressure of the recess equal to the pressure of the discharge chamber. And Roll compressor.