KR19980067631A - Displacer guide device for Stirling cycle machines - Google Patents

Abstract

The present invention relates to a displacer guide device of a stirling cycle machine, and conventionally presses the guide ring pressed against the cylinder on the outer circumference of the displacer to fix the displacer due to the eccentric load of the displacer connecting rod. Since the guide ring is press-fitted to the outer periphery of the displacer, the diameter of the guide ring has to be increased so that the burden of material cost is increased and the machining accuracy is not easy, and the contact area with the cylinder is large. In the present invention, there is a problem that a large friction loss occurs, in the present invention, the guide rod is integrated with the cylinder, and the cylindrical guide groove is formed in the upper center of the displacer so that the guide rod is inserted. At the top of the guide, Since the sealing guide ring is pressed into the outer circumference of the guide rod, it is no longer necessary to mount a large diameter inclination guide ring on the outer circumference of the displacer, thereby minimizing mechanical loss due to friction. have.

Description

Displacer guide device for Stirling cycle machines

FIELD OF THE INVENTION The present invention relates to a stirling cycle machine, and more particularly to a displacer connecting rod guide of a stiring cycle machine which allows a uniform force to be applied from the displacer connecting rod to a straighter movement of the displacer while reducing mechanical losses. It is about.

In general, a stir cycle machine is a display that expands a working gas by using externally heated heat and obtains power by rotating a crankshaft by the expanded hot working gas, and performs a linear reciprocating motion by the working gas. Since the stand and the piston are coupled to the crankshaft and the connecting rod which rotates, respectively, the eccentric load (Eccentric Load or Side Force) is transmitted due to the rotational movement of the crankshaft, and thus the displacer may be tilted. The guide ring for sealing is integrated on the outer circumference of the stand to catch the eccentric load.

Figure 1 schematically shows the configuration of a Stirling cycle machine with a displacer equipped with a conventional guide ring for sealing.

As shown therein, an endothermic tube 2 heated by a separate heating means communicates with the upper side of the case (or cylinder head) 1, and one end of the endothermic tube 2 is made of a porous regenerator ( 3) is in communication with one side, the other side of the regenerator 3 is in communication with the radiator 4, the cylinder (instead of the case in Figure 1) (1 ') is pressed into the inside of the case (1), The displacer 6 is disposed above the inner circumference of the cylinder 1 'with a predetermined expansion space 5, and the piston 8 has a predetermined compression space 7 below the displacer 6. ) Is arranged, and a cross head 10 is disposed below the piston 8 with a predetermined reaction space 9, and below the cross head 10, the displacer 6 and the piston 8 are disposed. The crankshaft 11 is rotated by), and the displacer 6 and the piston 8 are displacer connecting rod 12 and a piece, respectively. Coupled with the crankshaft 11 by a connecting rod (13, 13 ') is configured such that the linear motion of the displacer (6) and the piston 8 is converted to a rotary motion of the crankshaft 11.

Here, at each outer circumference of the displacer 6, the piston 8, and the crosshead 10, sealing members 6a, 8a, 10a for sealing with the cylinder 1 ′ are press-fitted, among which the displacer 6 is pressed. The sealing material 6a pressed into the outer circumference of the s) acts as a guide ring for preventing the displacer 6 from being inclined by an eccentric load, and is generally referred to as a sealing guide ring.

Reference numeral 11a in the figure denotes a crankshaft bearing.

In the conventional stirling cycle device configured as described above, when the crankshaft 11 is rotated once by a separate power, the displacer 6 and the piston 8 coupled with the crankshaft 11 are inertial and By the action of the working gas to rotate the crank shaft (11) while continuing a linear movement up and down, where the operation of the Stirling cycle device by the working gas as follows.

That is, while the working gas heated by the endothermic tube 2 fills the expansion space 5 formed above the displacer 6, the expansion pressure first presses the displacer 6 from the top dead center to the bottom dead center. As the displacer 6 is pressed, the expansion space 5 is further enlarged, while the compression space 7 formed at the lower side of the displacer 6 is narrowed, so that the piston 8 also has the compression force. It is pressed from the top dead center to the bottom dead center with a predetermined time difference from the displacer 6. At this time, the displacer connecting rod 12 and the piston connecting rods 13 and 13 'are lowered to rotate the crank shaft 11 by 180 °.

Next, in the process of rapidly decreasing the pressure of the expansion space 5 together with the inertia force of the crankshaft 11, the displacer 6 is first lifted by the displacer connecting rod 12 while the piston 8 Is also raised by the piston connecting rods 13 and 13 'to rotate the crankshaft 11 further 180 degrees, at which time the displacer 6 tries to ascend first and receives the largest eccentric load. The eccentric load is transmitted to the sealing guide ring 6a as it is through the displacer 6 and canceled, while the displacer connecting rod 12 is eccentric while the displacer 6 reciprocates in a straight line. Had to get tilted by.

However, in the Stirling cycle device provided with the above-mentioned conventional sealing guide ring (6a), the displacer 6 to hold the displacer 6 due to the eccentric load of the displacer connecting rod 12 The guide ring 6a is pressed into the outer circumference of the cylinder 6 ', which is pressed against the outer circumference of the displacer 6 by the guide ring 6a. Since the diameter of the material must be large, the burden of the material cost is not only increased, but it is not easy to improve the degree of processing, and the contact area with the cylinder 1 'is large, resulting in a large friction loss.

Accordingly, an object of the present invention is to reduce the diameter of the guide ring to reduce the material cost for the guide ring as well as to improve the processing accuracy, and to reduce the friction loss by reducing the contact area with the cylinder. It is to provide a displacer guide of a sterling cycle machine that can be reduced.

1 is a schematic view showing the configuration of a conventional sterling cycle machine.

2 is a schematic view showing the configuration of a Stirling cycle machine according to the present invention.

Explanation of symbols on the main parts of the drawings

20: cylinder 21: displacer

21a: Cylindrical insertion groove Note 28: Guide rod

29: sealing guide ring

In order to achieve the object of the present invention, and displaces the expansion space and the compression space while moving up and down in the cylinder and the displacer is formed on the top surface of the cylindrical guide groove longer than the total length of the expansion space and the compression space; ; A displacer guide rod which is formed longer than the guide groove length of the displacer and is slidably inserted into the lower end of the cylinder head; Provided is a displacer guide device of a Stirring cycle machine, characterized in that it comprises a guide ring press-fitted to the outer periphery of the displacer guide rod is in close contact with the guide groove of the displacer.

Hereinafter, the displacer guide device of the Stirling cycle machine according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

As illustrated in FIG. 2, the Stirling cycle device equipped with a displacer guide device according to the present invention is divided into an expansion space 22 and a compression space 23 by the displacer 21. The displacer 21 is rotatably coupled with the displacer connecting rod 24 so that the displacer 21 linearly moves up and down during the rotational movement of the crankshaft 25. A piston 26 is disposed below the displacer 21. Disposed and rotatably coupled with the piston connecting rods 27, 27 ′, the piston connecting rods 27, 27 ′ being eccentric with the rotation center of the crank shaft 25 to rotate the crank shaft 25. It is configured to change the movement into the vertical movement of the piston 26.

The crankshaft 25 is formed to be eccentric with the rotational center of the portion coupled to the displacer connecting rod 24 and the portion coupled to the piston connecting rod 27, 27 'at a predetermined angle to each other and the displacer 21 ) And the movement point of the piston 26 is different.

Here, the displacer guide rod 28 is integrated at the center of the lower end surface of the cylinder 20, and the cylindrical guide groove 21a into which the guide rod 28 is slidably inserted is the upper surface of the displacer 21. It is formed in the center, the guide ring on the outer circumference of the guide rod 28 so that the guide ring 29 is disposed at a position opposite to the upper end of the guide groove 21a when the displacer 21 reaches the top dead center. (29) is press-fitted.

The guide ring 29 receives the greatest eccentric load when the bottom dead center of the displacer 21 is reached, that is, when the displacer 21 is pressed by the working gas and then tries to rise again, so that the displacer 21 is When the lowest point is reached, it is preferable to arrange the guide ring 29 so as to correspond to the upper end of the guide groove 21a.

In the drawings, the same reference numerals are given to the same parts as in the prior art.

In the drawings, reference numeral 2 denotes an endothermic tube, 3 a regenerator, 4 a radiator, 30 a crosshead, and 21b, 26a, and 30a are seals, respectively.

In the displacer guide device of the Stirling cycle machine according to the present invention configured as described above, when the crankshaft 25 is subjected to the trial rotation by a separate power, the crankshaft 25 and the respective connecting by the rotational force The displacer 21 and the piston 26 coupled to the rod 24 operate with the characteristics of the inertia force and the device. That is, while the working gas heated by the endothermic tube 2 fills the expansion space 22 formed above the displacer 21, the expansion pressure first presses the displacer 21 from the top dead center to the bottom dead center. As the displacer 21 is pressed, the expansion space 22 is further enlarged, while the compression space 23 formed at the lower side of the displacer 21 is narrowed, so that the piston 26 is also compressed by the compressive force. The displacer 21 is pressed from the top dead center to the bottom dead center with a predetermined time difference. At this time, the displacer 21 first starts lowering together with the displacer connecting rod 24, and then the piston 26 lowers together with the piston connecting rods 27 and 27 ′ to rotate the crankshaft 25 180. ° rotated.

Next, the displacer 21 first rises together with the displacer connecting rod 24 in the process of rapidly decreasing the pressure of the expansion space 22 together with the inertia force of the crankshaft 25, and then the piston. (26) rises together with the piston connecting rods 27, 27 'to rotate the crankshaft 25 further 180 degrees.

At this time, when the displacer 21 tries to ascend from the bottom dead center to the top dead center, the displacer connecting rod 24 receives the largest eccentric load from the crankshaft and is transmitted to the displacer 21, but the eccentricity is transmitted. The load is not transmitted to the sealing guide ring 21b press-fitted to the outer circumference of the displacer 21 but instead is transferred to the displacer guide rod 28 integrated into the cylinder 20 so that the cylinder 20 This will offset the eccentric load of.

Furthermore, since the guide ring 29 press-fitted to the displacer guide rod 28 is formed to be in close contact with the upper end of the inner circumference of the guide groove 21a, the eccentric load is received from the crankshaft 25 at the longest distance. The eccentric load transmitted to the guide ring 29 is reduced, so that the loss due to friction between the guide ring 29 and the displacer 21 is minimized.

As described above, the guide device of the Stirling cycle machine according to the present invention forms a cylindrical insertion groove, in which the guide rod is integrated into the cylinder, and the guide rod is slidably inserted in the upper center of the displacer so that the guide rod is inserted. By inserting the sealing guide ring into the outer circumference of the guide rod so that the guide ring is disposed on the upper end of the insertion groove, it is not necessary to install a large diameter anti-tilting guide ring on the outer circumference of the displacer. This has the effect of minimizing losses.

Claims (3)

A displacer which partitions the expansion space and the compression space while moving up and down within the cylinder, and a cylindrical guide groove longer than the total length of the expansion space and the compression space is formed on an upper surface thereof; A displacer guide rod which is formed longer than the guide groove length of the displacer and is slidably inserted into the lower end of the cylinder head; Displacer guide device of the Stirling cycle machine characterized in that it comprises a guide ring which is pressed against the outer periphery of the displacer guide rod is in close contact with the guide groove of the displacer. According to claim 1, wherein the cylindrical guide groove is formed in the center of the displacer, the displacer guide rod is formed in the center of the lower surface of the cylinder head, the displacer guide rod is characterized in that coupled to the center of the displacer Displacer guide device for cycle machines. The displacer guide device of claim 1, wherein the guide ring is disposed so as to correspond to an upper end of the guide groove when the bottom dead center of the displacer is reached.