JP4024605B2 - Scroll compressor with valve structure - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a valve structure suitable for a refrigeration cycle apparatus using CO2 as a refrigerant and a compressor including the same.
[0002]
[Prior art]
As a technique related to a conventional compressor valve structure, a technique disclosed in JP-A-8-319973 is known. This valve structure is applied to a discharge valve, in which a valve body and a seal surface are formed as rotating curved surfaces, respectively, and a line contact seal is formed when both come into contact with each other.
[0003]
As a result, the gap volume (dead volume) of the discharge port portion is made substantially zero to reduce the re-expansion loss.
[0004]
[Problems to be solved by the invention]
In recent years, a refrigeration cycle apparatus using CO2 having a lower warming coefficient as a refrigerant than environmental problems has been put into practical use. Since this refrigeration cycle apparatus is operated under a high pressure condition exceeding the critical pressure, the volume flow rate becomes very small, and the degree of influence of reexpansion loss due to the gap volume becomes very large for the compressor. As a matter of course, it is important for the compressor to ensure the strength of each member that can withstand high pressure conditions.
[0005]
Therefore, in a compressor using CO2 as a refrigerant, the diameter of the discharge flow path (hole diameter) for accommodating the valve body of the discharge valve is made as small as possible in order to ensure strength based on the above-described conventional technology capable of reducing the gap volume. Correspondingly, it can be considered that the valve body itself is also made smaller. However, as the valve structure is reduced in size, foreign matter generated in the refrigeration cycle apparatus or in the compressor itself is likely to be caught on the valve body, which may interfere with the operation of the valve body and thus cause a decrease in the performance of the compressor. Is done.
[0006]
In view of the above problems, an object of the present invention is to provide a valve structure that is excellent in reliability against foreign matters while suppressing the clearance volume of the discharge port portion, and a compressor including the valve structure.
[0007]
[Means for Solving the Problems]
In order to achieve the above object, the present invention employs the following technical means.
[0008]
In the first aspect of the present invention, CO2 is used as a refrigerant , and this refrigerant is compressed and discharged, and the compressed refrigerant from the two working chambers (152) joins at the center of the fixed scroll (140). In the compressor,
A partition plate (140) separating the working chamber (152) and the discharge chamber (153);
A discharge port (141) that opens as a circular hole on the working chamber (152) side of the partition plate (140);
A discharge channel (142) communicating with the discharge port (141), having a large diameter and substantially concentrically, and opening as a circular hole on the discharge chamber (153) side of the partition plate (140);
A valve body (161) in contact with a seal surface (143) formed at the boundary between the discharge port (141) and the discharge flow path (142);
A coil spring (162) disposed in the discharge channel (142) and biasing the valve body (161) toward the working chamber (152) by the seal surface (143);
The valve body (161) is provided on the side opposite to the discharge port, has a cylindrical large diameter portion and a small diameter portion, the large diameter portion is inserted and fixed to the inner wall of the discharge flow path (142), and the small diameter portion is a coil spring (162). A stopper (163) that is inserted into the inner circumference of the valve and supports the coil spring (162) and restricts the lift amount (d) when the valve body (161) is opened,
A valve structure (160) having a groove (144) recessed toward the working chamber (152) on the outer peripheral side of the seal surface (143) ;
At least one of the width (L) dimension and the depth (D) dimension of the groove (144) is set larger than the lift amount (d),
The valve structure (160) is provided as a sub-discharge valve portion (160b) at a predetermined portion of the two working chambers (152) .
[0009]
Thus, after the valve body (161) is opened and foreign matter flows out from the discharge port (141), the foreign matter in the vicinity of the valve body (161) is absorbed into the groove (144) when the valve body (161) is closed. Since it becomes difficult to be caught between the sealing surface (143) and the valve body (161), the reliability of the function of the valve body (161) can be improved.
[0010]
Further, since the sealing surface (143) of the valve body (161) is formed between the protruding port (141) in the partition plate (140) and the discharge flow path (142), the volume of the discharge port (141), that is, The gap volume can be easily reduced and reexpansion loss can be reduced.
[0011]
The valve structure is simple, and the discharge port (141), the discharge flow path (142), and the valve body (161) can be easily downsized, and the partition plate (140) is secured. Thus, sufficient strength under high pressure conditions using CO2 as a refrigerant can be ensured.
[0013]
Further, since at least one of the width (L) dimension and the depth (D) dimension of the groove (144) is set larger than the lift amount (d) when the valve body (161) is opened, the valve body ( the foreign matter that flows out from 161) can be reliably absorbed by the groove portion (144), further it is possible to improve the reliability of the valve element (161) functions.
[0014]
In addition, in the case of having a plurality of valve structures (160) according to the arrangement or number of working chambers (152), the probability that foreign matter is caught increases, so this valve structure (160) is particularly effective.
In the second aspect of the present invention, the discharge port (141) is opened so that the opening diameter (ΦB) opened to the valve body (161) is larger than the inner diameter dimension (ΦA2) of the discharge port (141). The inner wall of the port (141) is formed in a taper shape.
In the invention according to claim 3, a plurality of guide portions (161a) inscribed in the discharge flow path (142) and a notch portion (161b) for circulating the refrigerant are formed on the outer periphery of the valve body (161). Further, the depth dimension (h) and the width dimension (w) of the notch (161b) are set to be larger than the lift amount (d), respectively.
The invention according to claim 4 is characterized in that the valve structure (160) is provided as a main discharge valve portion (160a) also in the central portion of the fixed scroll (140).
In the invention according to claim 5, the inner diameter dimension (ΦA1) of the discharge port (141) of the main discharge valve section (160a) is larger than the inner diameter dimension (ΦA2) of the discharge port (141) of the sub-discharge valve section (160b). It is characterized by the fact that it is also made larger.
[0015]
In the invention described in claim 6, the opening diameter of the opening in the valve body (161) side of the discharge port (141) in a plurality of valve structure (160) (.PHI.B) are all formed on the same valve body (161) Are all characterized by the same specification.
[0016]
As a result, even when the inner diameter of the discharge port (141) is different, the valve opening pressure applied to the valve body (161) can be made the same, so that the valve body (161) can be made common and inexpensive. can do.
[0017]
In addition, the code | symbol in the bracket | parenthesis of each said means shows a corresponding relationship with the specific means of embodiment description mentioned later.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
A first embodiment of the present invention will be described with reference to FIGS. The compressor 100 is applied to a refrigeration cycle apparatus (not shown) that uses CO2 as a refrigerant, and is an electric compressor in which the compressor unit 130 is operated by a motor unit 120 incorporated therein.
[0019]
The motor unit 120 and the compressor unit 130 are accommodated in a housing 110 as a sealed container formed by welding a front housing 111, a middle housing 112, and an end housing 113 to each other. The front housing 111 is provided with a suction port 111a through which refrigerant is sucked.
[0020]
A support plate 114 and a frame 115 to which bearings 132 and 133 are respectively fixed are provided on the front housing 111 side and an intermediate portion in the middle housing 112, and the drive shaft 131 is rotatably supported by the bearings 132 and 133. Has been.
[0021]
The motor unit 120 includes a rotor unit 121 and a stator unit 122. The rotor part 121 is fixed to the drive shaft 131, and the stator part 122 is fixed to the inner peripheral surface of the middle housing 112 by press-fitting on the outer peripheral side of the rotor part 121. When power from an external power source (not shown) is supplied to the stator unit 122, the drive shaft 131 is driven to rotate as the rotor unit 121 rotates. The support plate 114 is provided with a flow path 114a through which the refrigerant sucked from the suction port 111a flows into a space in which the motor unit 120 in the middle housing 112 is accommodated.
[0022]
The compressor unit 130 constitutes a known scroll compressor having a movable scroll 135 and a fixed scroll 140. The fixed scroll 140 is fixed to the side opposite the motor in the middle housing 112, and a movable scroll 135 is disposed so as to mesh with the fixed scroll 140.
[0023]
An eccentric portion 131 a provided at the tip of the drive shaft 131 is inserted through a bearing 134 on the side of the movable scroll 135 opposite to the fixed scroll. The movable scroll 135 revolves with respect to the fixed scroll 140 as the drive shaft 131 is driven to rotate by a rotation prevention mechanism (not shown).
[0024]
A suction chamber 151 is formed on the outer peripheral side between the scrolls 135 and 140, and a working chamber 152 is formed toward the center side. The frame 114 is formed with a flow passage 115 a through which the refrigerant flowing into the space in which the motor unit 120 is accommodated flows into the suction chamber 151.
[0025]
A discharge chamber 153 connected to the discharge port 112a is formed in the fixed scroll 140, and a discharge valve portion (valve structure) 160 serving as a feature of the present invention is provided between the working chamber 152 and the discharge chamber 153. It has been. In the scroll compressor 100, discharge valve portions 160 are provided at a total of three locations, that is, a central portion of the fixed scroll 140 where the compressed refrigerant from the two working chambers 152 merges and a predetermined portion in the two working chambers 152. The central discharge valve portion 160 is a main discharge valve portion 160a, and the other two are sub discharge valve portions 160b.
[0026]
Since the basic configuration of the discharge valve portion 160 is the same for all three, the main discharge valve portion 160a at the center will be described as a representative in detail with reference to FIGS.
[0027]
The discharge valve section 160 includes a valve body 161, a spring 162, and a stopper 163 provided in the discharge flow path 142 among the discharge port 141 and the discharge flow path 142 provided as circular holes in the fixed scroll 140. The fixed scroll 140 corresponds to a partition plate that partitions the working chamber 152 and the discharge chamber 153 in the present invention.
[0028]
The discharge port 141 is a small-diameter hole that opens to the working chamber 152 side, and the diameter dimension and the axial dimension are set as small as possible. The discharge flow path 142 is a flow path that communicates with the discharge port 141 and opens toward the discharge chamber 153, has an inner diameter dimension larger than that of the discharge port 141, and is disposed substantially concentrically.
[0029]
A seal surface 143 is formed at the boundary between the discharge port 141 and the discharge flow path 142, and a disc-like valve body 161 is urged toward the working chamber 152 by a spring 162 on the seal surface 143. Touching. Further, a stopper 163 is provided on the side opposite to the discharge port of the valve body 161 so as to regulate the lift amount d when the valve body 161 is opened by a predetermined discharge pressure from the working chamber 152.
[0030]
On the outer periphery of the valve body 161, a plurality of guide portions 161a inscribed in the discharge flow path 142 and a notch portion 161b for circulating the refrigerant are formed. The depth dimension h and the width dimension w of the notch 161b are set to be larger than the lift amount d.
[0031]
Further, a groove portion 144 that is recessed toward the working chamber 152 is provided on the outer peripheral side of the seal surface 143. Both the width dimension L and the depth dimension D of the groove 144 are set so as to be larger than the lift amount d similarly to the guide part 161a and the notch part 161b of the valve body 161. In addition, you may set so that any one of the width dimension L and the depth dimension D may become larger than the lift amount d.
[0032]
Further, as shown in FIG. 4, the main discharge valve portion 160a and the sub discharge valve portion 160b have different discharge flow rates of the refrigerant, so that the inner diameter dimension of each discharge port 141 is φA1> φA2. . That is, the discharge port diameter on the main discharge valve portion 160a side where the discharge flow rate is large is made large. However, the opening area (φB in terms of opening diameter) that opens to the valve body 161 side of the discharge port 141 is the same for both the main and sub discharge valve portions 160a and 160b, and the valve body 161, the spring 162, and the stopper 163 are each The discharge valve portions 160a and 160b are all set to the same specification.
[0033]
Next, the operation and effect based on the above configuration will be described. In the compressor 100, the movable scroll 135 is revolved by driving of the motor unit 120, and the refrigerant flowing into the suction chamber 151 through the suction port 111 a and the flow passages 114 a and 115 a is compressed in the working chamber 152. At this time, the refrigerant flows through the motor unit 120, whereby the motor unit 120 is cooled.
[0034]
When the refrigerant compressed in the working chamber 152 reaches a predetermined discharge pressure, the valve bodies 161 of the discharge valve portions 160a and 160b are regulated and opened by the lift amount d, and the refrigerant is disconnected from the discharge port 141 and the valve body 161. The ink is discharged from the discharge port 112a through the notch 161b, the discharge flow path 142, and the discharge chamber 153.
[0035]
By the way, in the refrigeration cycle apparatus and the compressor 100 itself, there are foreign matters such as fine chips and chips generated when each member is molded, and it flows together with the refrigerant. In the present invention, since the groove portion 144 is formed on the outer peripheral side of the seal surface 143, the foreign matter in the vicinity of the valve body 161 is closed when the valve body 161 is closed after the valve body 161 is opened and the foreign matter flows out from the discharge port 141. Can be absorbed in the groove portion 144 to make it difficult to be caught between the seal surface 143 and the valve body 161, and the reliability of the function of the valve body 161 can be improved.
[0036]
Here, since the width dimension L and the depth dimension D of the groove portion 144 are both larger than the lift amount d of the valve body 161, the foreign matter that can flow out from the valve body 161 can be surely absorbed into the groove portion 144. Yes.
[0037]
Further, with respect to a plurality of discharge valve portions 160a and 160b, the opening area (opening diameter φB) of the discharge port 141 that opens to the valve body 161 side is all the same, and the valve body 161, the spring 162, and the stopper 163 are shared. It is a specification, and it can be cheaply supported.
[0038]
This is because even if the inner diameters of the discharge ports 141 are different, by making the opening area opened to the discharge valve 161 side the same, the valve opening force applied to the valve body 161 can be made the same and shared. .
[0039]
Since the sealing surface 143 of the valve body 161 is formed between the protruding port 141 and the discharge flow path 142 in the fixed scroll 140, the volume of the discharge port 141, that is, the gap volume can be easily reduced, and the re-expansion loss. Can be reduced.
[0040]
Further, the valve structure is a simple configuration, the discharge port 141, the discharge flow path 142, and the valve body 161 can be easily downsized, the thickness of the fixed scroll 140 is secured, and high pressure using CO2 as a refrigerant. Sufficient strength under conditions can be secured.
[0041]
(Second Embodiment)
A second embodiment of the present invention is shown in FIG. In the second embodiment, the valve body 161 is formed in a hemispherical shape, and the valve body 161 side of the discharge port 141 is opened so as to open in a conical shape to form a seal surface 143. A groove 144 is formed on the outer peripheral side of the seal surface 143.
[0042]
As a result, as in the first embodiment, the groove 144 prevents the foreign matter from being caught, and enables sealing with a line on the circumference where the valve body 161 and the discharge port 141 are in contact with each other. Can be further reduced to reduce re-expansion loss.
[0043]
(Reference example)
In the first and second embodiments described above, the scroll type compressor unit 130 is used. However , another type of compressor unit 130 is shown . FIG. 6 shows an example in which the compressor unit 130 has two compression units 130a and is applied to a two-stage rotary type that boosts and compresses. Here, two rotors 136 are provided on the drive shaft 131, and a discharge valve portion 160 is provided between the working chamber 152 and the discharge chamber 153. The valve body 161, the spring 162, and the stopper 163 that form the two discharge valve portions 160 have the same specifications as in the first embodiment.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a compressor in a first embodiment of the present invention.
2 is an enlarged view showing a discharge valve portion in FIG. 1. FIG.
FIG. 3 is an arrow view showing a valve body from the direction A in FIG. 2;
FIG. 4 is an enlarged view showing main and sub discharge valve portions.
FIG. 5 is an enlarged view showing a discharge valve portion in a second embodiment of the present invention.
FIG. 6 is a cross-sectional view showing a compressor according to another embodiment.
[Explanation of symbols]
100 Compressor 140 Fixed scroll (partition plate)
141 Discharge port 142 Discharge flow path 143 Seal surface 144 Groove 152 Operating chamber 153 Discharge chamber 161 Valve element

Claims (6)

The CO2 as a refrigerant, compresses the refrigerant, be those discharges, in the scroll type compressor compressing the refrigerant from the two working chambers (152) are joined at the center of the fixed scroll (140),
Said actuating chamber (152) and a discharge chamber (153) a partition plate that partitions between the (140),
A discharge port (141) opening as a circular hole on the working chamber (152) side of the partition plate (140);
A discharge channel (142) that communicates with the discharge port (141), has a large diameter and is substantially concentric, and opens as a circular hole on the discharge chamber (153) side of the partition plate (140). When,
A valve body (161) in contact with a seal surface (143) formed at a boundary between the discharge port (141) and the discharge flow path (142);
A coil spring (162) disposed in the discharge flow path (142) and biasing the valve body (161) toward the working chamber (152) by the seal surface (143);
The valve body (161) is provided on the side opposite to the discharge port and includes a cylindrical large diameter portion and a small diameter portion, the large diameter portion is inserted and fixed to the inner wall of the discharge flow path (142), and the small diameter portion is A stopper (163) which is inserted into the inner periphery of the coil spring (162) to support the coil spring (162) and regulates the lift amount (d) when the valve body (161) is opened;
A valve structure (160) having a groove (144) recessed toward the working chamber (152) side on the outer peripheral side of the seal surface (143) ;
At least one of the width (L) dimension and the depth (D) dimension of the groove (144) is set larger than the lift amount (d),
A scroll type compressor, wherein the valve structure (160) is provided as a sub-discharge valve part (160b) in a predetermined part of the two working chambers (152) .   The discharge port (141) has an opening diameter (ΦB) that opens to the valve body (161) side larger than an inner diameter dimension (ΦA2) of the discharge port (141). The scroll compressor according to claim 1, wherein the inner wall is formed in a tapered shape.   On the outer periphery of the valve body (161), a plurality of guide parts (161a) inscribed in the discharge flow path (142) and a notch part (161b) through which the refrigerant flows are formed.
  The depth dimension (h) and the width dimension (w) of the notch (161b) are set to be larger than the lift amount (d), respectively. Scroll compressor.   The said valve structure (160) is provided as a main discharge valve part (160a) also in the center part of the said fixed scroll (140), The Claim 1 characterized by the above-mentioned. Scroll compressor.   The inner diameter dimension (ΦA1) of the discharge port (141) of the main discharge valve section (160a) is made larger than the inner diameter dimension (ΦA2) of the discharge port (141) of the sub-discharge valve section (160b). The scroll compressor according to claim 4. Opening diameter which opens into the said valve body discharge port (141) (161) side at a plurality of said valve structure (160) (.PHI.B) are all formed on the same,
All the said valve bodies (161) are set as the same specification, The scroll compressor as described in any one of Claims 1-5 characterized by the above-mentioned.

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