KR200373297Y1 - Steam trap for radiator - Google Patents

Abstract

The present invention relates to a steam trap, and more particularly, by improving the structure of the steam trap used in the radiator, the high temperature steam pressure sent directly to the steam trap through the steam line is completely blocked by the opening or closing of the steam trap. It is to provide a steam trap for the radiator to be made.

To this end, the present invention has a body having a chamber in which the outlet is formed on the outer peripheral surface of the screw thread and the inlet formed in the decompression portion communicating; The cap is provided in the body in response to the temperature of the condensate flowing through the inlet port has a sealing space having an insertion space open to one side to automatically open / closed the decompression unit, and the coefficient of thermal expansion according to the temperature of the condensate in the sealing cap A bimetal disk having a plurality of discs convexly protruded by a metal different from each other in a plurality of layers, a valve stem provided so that the pressure reducing unit is sealed / opened according to the convex or circular return of the central portion of the bimetal disk; Restoration coil spring is provided so that the valve stem is returned to its original position when the bimetal disk is returned to its original position in the convex state, and the condensed water is coupled to the sealing cap and the condensed water flowing through the inlet is directly sensitive to the bimetal disk. A plurality of inflow holes and the valve stem is introduced So that it does not, and at the same time constructed as a sealing stopper for guided ball forming the valve opening and closing means; And a cover coupled to the body so that the valve opening and closing means provided in the body is sealed.

Description

Steam trap for radiator

The present invention relates to a steam trap, and more particularly, by improving the structure of the steam trap used in the radiator, the high temperature steam pressure sent directly to the steam trap through the steam line is completely blocked by the opening or closing of the steam trap. It relates to a steam trap for the radiator to be made.

In general, the steam trap (steam trap) is used for the discharge of condensed water generated by the condensation of steam in the steam space of the steam main line or heat exchanger of the production equipment using the steam, as shown in Figures 1 and 2 As described above, the conventional steam trap 10 has a structure in which an outlet 130 having a screw thread 130a is formed on an outer circumferential surface thereof horizontally, and an inlet port 150 having a decompression unit 150a is vertically formed. 130 and the inlet 150 is in communication with the body 100 defining a chamber 110 having a screw thread (110a) on the inner top; A cover 700 coupled to the body 100 to form a screw thread 700a on an outer circumferential surface and an inner circumference thereof to seal the chamber 110 and an incision space 700b formed on an inner space; The fastening hole 300c is formed at one end of the hollow portion 300b through which the screw line 300a is formed on the outer circumferential surface thereof and is engaged with the screw line 700a formed at the inner circumference of the cover 700 and coupled to the space portion. Insert member 300 is formed; A valve stem (400) having an insertion groove (400a) therein to open / close the pressure reducing part (150a); One end is coupled to the hollow portion 300b of the insert member 300 and the other end is coupled to the insertion groove 400a of the valve stem 400 to operate the valve stem 400 to operate the pressure reducing part 150a. A valve elevating member 500 provided with a summist 500b to expand / contract the pin 500a provided at one end of the inner end to be opened / closed according to a predetermined temperature; The valve lifting member which buffers the valve stem 400 which opens / closes the pressure reducing part 150a according to the operation of the valve lifting member 500 and flows in the hollow part 300b of the insert member 300. Compression coil springs 600 are provided on the inside of the insert member 300 and one side of the valve stem 400 so that the 500 is buffered.

In addition, a connection member 800 is coupled to the outlet 130 by the fastening member 900, and a packing 910 is provided between the outlet 130 and the connection member 800.

Therefore, the operation of the conventional stem trap 100 is to reduce the high temperature steam pressure sent to the steam trap 10 through the steam line as shown in Figure 2a in a pressure reducing device (not shown) to reduce the steam trap 10 Will be sent).

At this time, the vapor pressure reduced in the decompression device is in a state of maintaining a pressure of 3kg or less.

On the other hand, the condensed water is introduced through the inlet 150, the inlet condensed water is discharged to the outlet 130 through the chamber 110 in the decompression unit 150a of the steam tram 100 is open. The condensed water through the chamber 110 flows into the cutting space 700b of the cover 700 to which the insert member 300 is coupled, and at the same time, the valve elevating member 500 provided in the insert member 300. Heat is transferred to the condensate.

Subsequently, the valve elevating member 500 is provided to the valve elevating member 500 by heat transfer of the condensate and operates the fin 500a by expanding the thermost 500b which is expanded at a predetermined temperature. Together the valve stem 400 is operated.

On the other hand, the operation of the valve stem 400 is closed as shown in Figure 2b the decompression unit 150a to condense the water flowing into the steam trap 10 is blocked.

Here, when the temperature of the condensed water is lowered according to the operation of the valve stem 400, the vapor pressure is also lowered, and the valve stem 400, which seals the pressure reducing part 150a, is spaced apart from the pressure reducing part 150a. The decompression unit 150a is opened and, on the contrary, when the temperature of the condensate is raised, the vapor pressure is also increased, so that the valve stem 400 is closed again to seal the decompression unit 150a in an open state. The operation of the valve stem 400 is automatically performed.

In this case, the compression coil spring 600 provided in the insert member 300 together with the operation of the valve stem 400 and the compression coil spring provided between the valve stem 400 and the pressure reducing part 150a. 600, the valve stem 400 opens / closes the pressure reducing part 150a and is in a tension / compression state.

However, the conventional steam trap 10 is in the closed state of the pressure reducing unit 150a when the pressure of the steam sent to the steam trap 10 via the steam line in the state in which the pressure reducing unit 150a is closed is 3 kg or less. However, when the vapor pressure is 3kg or more, the closed state of the decompression unit 150a is not complete and the valve stem 400 sealing the decompression unit 150a is pushed together with the compression coil spring 600. Due to the problem that the decompression unit 150a is opened, a conventional decompression device capable of decompressing the vapor pressure discharged through the steam line to 3 kg or less is used.

The present invention is to solve the above problems, an object of the present invention is to improve the structure of the steam trap to block the high temperature steam pressure sent directly to the steam trap through the steam line, a separate pressure reducing the high temperature steam pressure It is to provide a steam trap for the radiator which is completely blocked without the pressure reducing device.

1 is an exploded perspective view showing a part of the conventional steam trap cutaway

2a and 2b is a functional diagram showing the operation of the conventional steam trip,

Figure 2a is a state diagram showing that the condensate is discharged to the outlet through the inlet in the open state of the pressure reducing portion of the steam trap

Figure 2b is a state in which the condensed water is blocked from entering the inlet in the closed state of the pressure reducing portion of the steam trap

Figure 3 is an exploded perspective view showing a partially cut steam trap of the present invention

4a and 4b is a functional diagram showing an operating state of the steam trap of the present invention,

Figure 4a is a state diagram showing that the condensate is discharged through the inlet to the outlet in the open state of the pressure reducing portion of the steam trap

4b is a state in which the decompression unit of the steam trap seals the decompression unit according to the deformation of the bimetal disc to prevent the inflow of condensate;

* Explanation of symbols for main parts of the drawings

1: steam trap 10: body

11: Chamber 115a: Pressure reducing section

30: bimetal disc 40: valve stem

50: Restoration coil spring 60: Closure stopper

70: cover

In order to achieve the above object, the present invention includes a body having a chamber in which an outlet formed in the outer peripheral surface of the screw thread and the inlet formed in the decompression unit is in communication; The cap is provided in the body in response to the temperature of the condensate flowing through the inlet, the sealing cap having an insertion space which is open to one side to automatically open / closed the decompression unit, and the thermal expansion in accordance with the temperature of the condensate in the cap A bimetal disk having a plurality of disks provided with convex protruding cores by a metal having different coefficients, and a valve stem provided with the pressure reducing part sealed / opened according to the convex or circular return of the central portion of the bimetal disk; Restoring coil spring is provided so that the valve stem is returned to its original position when the bimetal disc is returned to its original state from the convex state, and the condensed water is coupled to the sealing cap so that the condensed water flowing through the inlet is directly sensitive to the bimetal disc. A plurality of inlet holes and the valve stem into which condensed water So that it does not, and at the same time constructed as a sealing stopper for guided ball forming the valve opening and closing means; And The cover is coupled to the body so that the valve opening and closing means provided in the body is provided with a steam trap for a radiator comprising a.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 3 and 4.

Figure 3 is an exploded perspective view showing a partially cut in the stump trap of the present invention, Figure 4a and Figure 4b is a functional diagram showing the operating state of the steam trap of the present invention.

The present invention includes a body (10) having a chamber (11) in which an outlet (13) formed on the outer circumferential surface of the thread (13a) and an inlet (15) formed inside the pressure reducing unit (15a) are in communication; Sealing cap provided on the body 10 has a insertion space (20a) is open to one side to automatically open / closed the pressure-sensitive portion (15a) in response to the temperature of the condensate flowing through the inlet 15 Bimetal disk 30 and the bimetal disk 30 is provided in the sealing cap 20, the disc is provided in such a way that the center is convexly protruded by a metal having a different thermal expansion coefficient in accordance with the temperature of the condensate, and the bimetal The valve stem 40 is provided so that the decompression unit 15a is sealed / opened according to the convex or circular return of the center of the disk 30, and the valve stem when the bimetal disk 30 is returned to its original shape in the convex state. Restoration coil spring 50 is provided so that the 40 is returned to the original position, and the condensed water is coupled to the sealing cap 20 so that the condensed water flowing through the inlet 15 is directly sensitive to the bimetal disk 30. Condensate A valve opening / closing means including a plurality of inlet holes (60a) to be introduced and a sealing plug (60) formed at the same time as supporting the valve stem (40) so as not to be separated; And a cover 70 coupled to the body 10 to seal the valve opening and closing means provided in the body 10.

On the other hand, it is also used as a shape memory alloy instead of the bimetal disk 30, which protrudes convexly from the periphery when reaching a predetermined temperature.

The operation of the present invention configured as described above is as follows.

First, as shown in FIG. 4A, condensed water at a high temperature and steam pressure is introduced through the inlet port 15 of the steam trap 1 in a state in which the steam trap 1 of the present invention is directly installed in the steam line. In addition, the introduced condensate is discharged back to the outlet 13 through the chamber 11.

In this case, the valve opening and closing means provided in the chamber 11 to open / close the pressure reducing part 15a is operated by the temperature of the condensed water passing through the chamber 11, that is, to the sealing cap 20. The plurality of bimetal discs 30 overlapped are deformed into the convex state by the temperature of the condensed water introduced through the inlet hole 60a of the sealing stopper 60.

For example, each interval in the state in which the bimetal disk 30 deformed into the convex state and the bimetal disc in another convex state is overlapped in multiple sheets (in the present invention, shown in the state overlapped in five sheets) is spaced apart. In addition, the valve stem 40 is guided by the guide hole 60b of the stopper 60 by the spaced apart distance of the bimetal disk 30 is moved along with the tension of the restoring spring 50 to 4b As shown, the decompression unit 15a is sealed.

On the other hand, the bimetal disk 30 in the convex state until the temperature of the condensate is lowered while the valve stem 40 is to seal the decompression unit 15a while maintaining the current state, when the temperature of the condensate is lowered The central portion of the bimetal disc 30 in the convex state is returned to its original state, and the valve stem 40 is also returned to its original position by compression of the restoration coil spring 50 to open the decompression unit 15a.

Here, even if the condensate vapor pressure of 3 kg or more flowing into the depressurization unit 15a pressurizes the valve stem 40 sealing the depressurization unit 15a, the valve stem 40 is the bimetal in the convex state. The decompression unit 15a is sealed by the disk 30 to block the inflow of the condensate.

The present invention as described above is the vapor pressure of the condensate to pressurize the decompression unit 15a directly through the steam line when the condensate flowing through the decompression unit (15a) is 3kg or more to the decompression unit (15a) The valve stem 40 which seals the decompression unit 15a does not push even when pressurized, and thus the condensed water flowing through the decompression unit is excellent, and an additional decompression device is not required. Have.

Claims (2)

A body having a chamber in which an outlet formed on the outer circumferential surface of the screw line and an inlet formed on the inside of the pressure reducing unit communicate with each other; The cap is provided in the body in response to the temperature of the condensate flowing through the inlet, the sealing cap having an insertion space which is open to one side to automatically open / closed the decompression unit, and the thermal expansion in accordance with the temperature of the condensate in the cap A bimetal disk having a plurality of disks provided with convex protruding cores by a metal having different coefficients, and a valve stem provided with the pressure reducing part sealed / opened according to the convex or circular return of the central portion of the bimetal disk; Restoring coil spring is provided so that the valve stem is returned to its original position when the bimetal disk is returned to its original position in the convex state, and the condensed water is coupled to the sealing cap and the condensed water flowing through the inlet is directly sensitive to the bimetal disk. A plurality of inlet holes and the valve stem into which condensed water And valve opening and closing means consisting of a closure cap which is supported while preventing the guide hole is formed; And A cover coupled to the body such that the valve opening and closing means provided in the body is sealed; Steam trap for the radiator, characterized in that comprises a. The method of claim 1, A steam trap for a radiator, wherein the bimetal disc, which protrudes convexly from the periphery when a predetermined temperature is reached, is a shape memory alloy.