KR102308271B1 - Temperature sensitive shutoff valve - Google Patents

Abstract

The present invention relates to a temperature sensitive shutoff valve (TRSV) (100) for a fluid, the TRSV (100) having a first open end (10), a second open end (20), a third open end (30) and a second and a housing (50) having four open ends (40). The temperature-responsive shut-off valve according to the present invention uses a gamma member 24a to reduce wear. Also, the effort of manual reset is reduced by the cam 26 being guided over the shape of the piston 42 . In addition, by the temperature response element 34 of the TRSV 100, the liquid sample is provided at a temperature below a predetermined temperature to provide improved safety to the liquid analyzer.

Description

Temperature sensitive shutoff valve

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to valves for fluids, and more particularly, to a temperature-sensitive shut-off valve.

Many industrial processes require the measurement of contaminants to ensure the quality of the liquid passing through the facility. The most common method of measuring the quality of a liquid is to pass a representative liquid sample through various analyzers to measure the quality of the sample. Sometimes these analyzers are required to condition the sample below a certain pressure and temperature, which may cause the analyzer to fail if the pressure or temperature of the sample being analyzed exceeds these limits. It is therefore very important to protect the analyzer from temperature rise. It is also important to shut off the fluid flow to the analyzer until the root cause of the increased sample temperature is diagnosed and addressed.

U.S. Patent No. 5826790 discloses a temperature sensing valve for treating a liquid, the valve having a housing having a valve seat and on the seat (blocking flow) from a first position spaced from the seat (allowing flow). and a valve member mounted to move to the second position. When the temperature of the liquid is below the shut-off temperature, a locking device is coupled to the valve member, whereby the member is configured to hold the member in the first position. A temperature sensitive device is mounted to the valve body while including an actuator coupled to the locking device. The valve body comprises a chamber with a sensing part of the temperature sensitive device, and also comprises a flow hole, whereby liquid flows out when the valve is opened and contacts the sensing part so as to provide a quick response with good heat transfer. When the temperature of the liquid is above the shut-off temperature, the locking device is released and the valve member moves to the second position. Accordingly, it is possible to prevent the equipment from being exposed to a liquid having a temperature that can damage the sensitive analysis equipment.

German patent DE20306025 discloses a thermally closed valve, which has an expanding member acting mechanically, while being able to shut off the liquid flow immediately without the need for external energy supply by means of an axially moving sliding member and a suitable sealing ring. is configured to The device operates without current and uses a spring-loaded mechanism to achieve very fast hermetic pressure seals of up to 400 bar without output power.

However, the temperature-sensitive shut-off valve mentioned in the prior art as described above has the following disadvantages.

go. Since the conventional valve uses a spherical ball or pin that moves in both directions, it is difficult to reset the valve.

me. Conventional valves do not use antifriction members, resulting in wear of valve components.

all. Conventional valves require more manual force to reset.

La. Conventional valves do not have a relief valve.

Accordingly, there is a need to provide a temperature-sensitive shut-off valve capable of overcoming the aforementioned disadvantages.

It is an object of the present invention to provide a temperature-sensitive shut-off valve capable of reducing wear.

Another object of the present invention is to provide a temperature sensitive shut-off valve capable of reducing the manual work required for resetting.

Another object of the present invention is to provide a temperature-sensitive shut-off valve with improved safety.

The present invention provides a temperature sensitive shutoff valve (TRSV) 100 for a fluid. The TRSV 100 includes a housing 50 having a first open end 10 , a second open end 20 , a third open end 30 and a fourth open end 40 .

The TRSV 100 further includes a first cap 12 disposed on the first open end 10 . The first cap 12 includes at least one port. The port acts as an inlet for the fluid sample, and the inlet is connected to the chamber 51 and the chamber 52 . A first cap 12 is surrounded by a chamber 52 while a ball 14 disposed to move freely within the chamber 52 , and a pin 16 disposed to retain the ball 14 within the chamber 52 . further includes The first cap 12 also includes a plurality of tapered holes 12a configured to facilitate the introduction of fluid from the inlet to the housing 50 .

The TRSV 100 further includes a second cap 22 disposed on the second open end 20 of the housing 50 . The second cap 22 includes a shaft 24 disposed therein. The shaft 24 is configured to be movable in the axial direction, and in one embodiment, the shaft 24 is guided by a gamma member 24a.

In addition, the second cap 22 includes a cam 26 connected to the shaft 24 inside the housing 50 , a screw 28 disposed on the shaft 24 at the side of the third open end 30 of the housing. , and a spring 22a disposed within the cap 22 .

The TRSV 100 also includes a third cap 32 disposed on the third end 30 of the housing 50 . The third cap 32 includes a temperature responsive element 34 disposed within the cap 32 and is configured such that a flow of fluid passes through the temperature responsive element 34 before exiting through the outlet. The third cap 32 further includes a pin 36 disposed on the temperature responsive element 34 to impart a stroke when the temperature of the fluid passing through the temperature responsive element 34 rises above the trigger temperature. configured to do In particular, it is configured to adjust the gap between the shaft 24 and the pin 36 by means of a screw 28 .

The TRSV 100 also includes a piston 42 disposed on the fourth open end 40 of the housing 50 . The piston 42 includes a cam profile slot 42a. Specifically, the piston is guided by a bush 42b and a nut 42c at one end, and a pin 16 of the chamber 52 at the other end. The piston 42 also includes a spring 44 wound thereon, so that the piston 42 is configured to move axially within the housing 50 . Also, the reset lever 46 is configured to pivot relative to the piston 42 .

Specifically, when the temperature of the fluid reaches the trigger temperature value, the pin 36 of the temperature response element 34 starts to push the screw 28 thereby moving the shaft 24 while compressing the reset spring 22a. do. Then, the cam 26 guides the cam profile 42a of the piston 42, thereby pushing the piston 42 forward by the expansion of the spring 44 while the pin 16 catches the ball 14. configured to close the inlet by pushing.

A temperature-sensitive shut-off valve capable of reducing wear is provided in accordance with the present invention. In addition, a temperature-sensitive shut-off valve with improved safety is provided, which can reduce the manual operation required for resetting.

1 shows a temperature-sensitive shut-off valve in an open state, according to the invention;
Figure 2 shows the reset button position when the temperature sensitive shut-off valve is in the open position.
3 shows a temperature-sensitive shut-off valve in a closed state according to the present invention;
4 shows the reset button position when the temperature sensitive shut-off valve is in the closed state.
5 shows a temperature sensitive shut-off valve with an alarm contact in one embodiment of the present invention.

The objects of the present invention described above and the problems and disadvantages posed in the prior art are achieved and overcome by the present invention described in the following preferred embodiments.

Accordingly, the present invention provides a temperature-sensitive shut-off valve. Temperature sensitive shutoff valves use an antifriction element configured to reduce wear. Also, the effort of manual reset can be reduced by the cam guided over the shape of the actuator. In addition, the temperature-sensitive shut-off valve of the present invention can provide improved safety to the liquid analyzer by providing a liquid sample at a predetermined temperature or less.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention is described with reference to the accompanying drawings, in which parts are assigned reference numerals so as to indicate correspondingly identical parts in the various drawings. These reference numbers are indicated in parentheses in the description below.

Referring now to FIGS. 1 to 4 , a temperature sensitive shutoff valve 100 (hereinafter referred to as “TRSV 100”) is shown. The TRSV 100 includes a housing 50 . The housing 50 includes a first open end 10 , a second open end 20 , a third open end 30 and a fourth open end 40 .

The first open end 10 of the housing 50 includes a first cap 12 disposed thereon. The first cap 12 includes at least one port disposed thereon. In particular, the port acts as an inlet for the fluid sample, and the inlet is connected to the chamber 51 and the chamber 52 as shown in FIG. 1 . A first cap 12 is surrounded by a chamber 52 while a ball 14 disposed to move freely within the chamber 52 , and a pin 16 disposed to retain the ball 14 within the chamber 52 . further includes The first cap 12 also includes a plurality of tapered holes configured to facilitate the inlet of fluid from the inlet to the housing 50 when the TRSV 100 is in an open state.

In one embodiment, the first cap 12 is configured to close the valve by including a plug disposed to move freely within the chamber 52 .

The second open end 20 of the housing 50 also includes a second cap 22 disposed thereon. The second cap 22 includes a shaft 24 disposed therein. In particular, the shaft 24 is configured to be movable in the axial direction. In one embodiment, the shaft 24 is guided by a gamma member 24a. The second cap 22 further includes a cam 26 connected to the shaft 24 inside the housing 50 . In another embodiment, the second cap 22 further comprises a screw 28 disposed on the shaft 24 at the side of the third open end 30 of the housing, and a spring 22a. The spring 22a in the cap 22 is used to reset the TRSV 100 . In particular, the gamma member 24a maintains the concentricity of the shaft 24 within the second cap 22 .

The third open end 30 of the housing 50 also includes a third cap 32 disposed thereon. The third cap 32 includes a temperature responsive element 34 disposed within the cap 32 and is configured such that a flow of fluid passes through the temperature responsive element 34 before exiting through the outlet. The third cap 32 further includes a pin 36 disposed on the temperature responsive element 34 to impart a stroke when the temperature of the fluid passing through the temperature responsive element 34 rises above the trigger temperature. configured to do In particular, it is configured to adjust the gap between the shaft 24 and the pin 36 by means of a screw 28 . In one embodiment, the temperature responsive element used is wax.

The fourth open end 40 of the housing 50 also includes a piston 42 disposed thereon. The piston 42 includes a cam profile slot 42a disposed thereon. Specifically, the piston is guided at one end by a bush 42b and a nut 42c and at the other end, that is, at the end of the cam profile 42a by a pin 16 of the chamber 52 . The piston 42 also includes a spring 44 wound thereon such that the piston 42 can move axially within the housing 50 , and a reset lever 46 configured to pivot on the piston. Specifically, the opening and closing of the TRSV 100 is determined by the spring 44 . The reset lever 46 is configured to pivot relative to the piston 42 and can be used to facilitate a closing indication of the TRSV 100 and to set the valve to the open state.

As shown in FIG. 5 , the fourth open end 40 also includes an alarm contact 61 mounted thereon, thereby configured to signal when the TRSV 100 is activated. When the TRSV 100 is opened, a pin (not shown) of the alarm contact contacts the piston 42 . When the TRSV 100 is closed, the piston 42 is disengaged from the pin of the alarm contact 61 by disengaging it.

As shown in FIG. 1 , at the initial stage of operation, the TRSV 100 is in an open state, and the reset lever 46 is configured as shown in FIG. 2 . The cam 26 rests on the vertical plane of the cam profile 42a of the piston 42 and stops the forward movement of the piston 42 . In addition, the concentricity of the second cap 22 and the shaft 24 receiving the load of the spring 22a by the sliding bearing is maintained.

Specifically, the liquid or fluid enters the housing 50 through the inlet port, passes through the chamber 52 , passes through the temperature response element 34 , and then is discharged through the outlet of the third cap 30 .

More specifically, when the temperature of the liquid reaches the trigger temperature value, the pin 36 of the temperature responsive element 34 starts to push the screw 28 . The screw 28 is an adjustment screw, and when the shaft 24 moves, it compresses the reset spring 22a.

At the same time, the cam 26 guides the cam profile 42a of the piston 42 . When the cam 26 is guided over the inclined cam profile 42a of the piston 42 , the piston 42 moves forward due to the expansion of the spring 44 as the lock is removed. Since the pin 16 of the chamber 52 is located at the end of the cam profile 42a of the piston 42, as the pin 16 pushes the spherical ball 14 to close the inlet, finally the TRSV 100 is configured to close.

During the forward movement of the piston 42 , the reset lever 46 rotates about the pivot due to its shape guided over the nut 42c, moving to a position away from the valve as shown in FIG. 4 . This position represents the closed state of the TRSV 100 . The TRSV 100 remains closed until manually reset.

In one embodiment, the TRSV 100 may be manually reset only when the temperature inside the valve sensed by the temperature response element 34 drops below the trigger temperature. When this state is reached, it is configured to reset the TRSV 100 by manually pushing the reset lever 46 toward the TRSV 100 . The backward movement of the piston 42 compressing the spring 44 is facilitated by the pressing of the reset lever 46 . The expansion of the spring 22a causes the shaft 36 to move downward while the cam 26 is guided over the cam profile 42a of the piston 42 and rests on the vertical surface of the cam profile 42a. In this position, the mechanism engages the locking mechanism even if the force on the reset lever 46 is removed. TRSV 100 is now open.

In one embodiment, a sensor (not shown) is mounted on the TRSV 100 , thereby providing an electrical output indicative of the “open” and “closed” states of the TRSV 100 , and thus the remote control of the TRSV 100 . It is configured to enable monitoring.

Advantages of the temperature sensitive shutoff valve (TRSV) 100 according to the present invention are summarized as follows.

1. All four sides can be guided with smooth operation.

2. Low wear due to the use of anti-gamma elements.

3. Even a small displacement of the pin of the temperature response element can cause a large displacement in the device.

4. Provides low reset time due to convection cooling of the temperature-responsive element.

The foregoing description of specific embodiments of the invention has been presented for purposes of illustration and description, and they are not intended to limit or reduce the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teachings. The present embodiments were chosen and described so as to best explain the principles of the invention and its practical application, thereby enabling those skilled in the art to best utilize the various embodiments with the invention and various modifications as are suited to the particular use intended. Various omissions and substitutions of equivalents may be contemplated, which may be suggested or appropriate depending on circumstances, but are intended to cover their application or implementation without departing from the spirit or scope of the invention.

Claims (9)

Temperature sensitive shutoff for fluid including housing 50 , first cap 12 , second cap 22 , third cap 32 , piston 42 , spring 44 and reset lever 46 . In the valve (100),
The housing (50) includes a first open end (10), a second open end (20), a third open end (30) and a fourth open end (40),
The first cap (12) is disposed on the first open end (10),
- at least one port serving as an inlet for a fluid sample; The inlet is connected to the chamber 51 and the chamber 52,
- at least one ball (14) surrounded by the chamber (52) and arranged to move freely within the chamber (52); and
- a pin (16) arranged to retain the ball (14) in the chamber (52);
The second cap 22 is disposed on the second open end 20 of the housing 50,
- a shaft 24 arranged in the second cap and movable in the axial direction;
- a cam 26 connected to the shaft 24 on the inside of the housing 50 ; and
- a spring (22a) disposed in the cap (22);
The third cap 32 is disposed on the third open end 30 of the housing 50,
- a temperature responsive element 34 arranged in the cap 32 such that the flow of fluid passes through the temperature responsive element 34 before exiting through the outlet;
a pin (36) disposed on the temperature-responsive element (34) to impart a stroke when the temperature of the fluid passing through the temperature-responsive element (34) rises above the trigger temperature; configured to adjust the gap between the shaft 24 and the pin 36 by
The piston 42 is disposed on the fourth open end 40 of the housing 50, the piston 42 comprising a cam profile slot 42a, the piston having a bush 42b and a nut 42c at one end. ), guided by the pin 16 of the chamber 52 at the other end,
The spring 44 is disposed on the piston 42 , such that the piston 42 is configured to allow axial movement within the housing 50 ,
The reset lever (46) is pivoted relative to the piston (42),
When the temperature of the fluid reaches the trigger temperature value, the pin 36 of the temperature response element 34 begins to push the screw 28 thereby moving the shaft 24 and compressing the reset spring 22a, and then the cam 26 guides the cam profile 42a of the piston 42, thereby pushing the piston 42 forward by the expansion of the spring 44, while the pin 16 pushes the ball 14 into the inlet characterized in that it is configured to close
Temperature sensitive shut-off valve. According to claim 1,
The shaft (24) is guided by a gamma member (24a) in the second cap (22).
Temperature sensitive shut-off valve. According to claim 1,
The shaft (24) comprises a screw (28) disposed on the shaft at the side of the third open end (30) of the housing.
Temperature sensitive shut-off valve. According to claim 1,
The reset lever 46 is configured to close the valve by moving it to a position away from the valve, rotating about the pivot due to the shape that guides over the nut 42c as the piston 42 moves in the forward direction. characterized
Temperature sensitive shut-off valve. According to claim 1,
The first cap (12) of the first open end (10) comprises a plurality of tapered holes (12a) configured to facilitate the inflow of fluid from the inlet into the housing (50).
Temperature sensitive shut-off valve. According to claim 1,
The temperature sensitive shutoff valve 100 is reset by manually pushing the reset lever 46 towards the temperature sensitive shutoff valve 100 only when the temperature inside the valve sensed by the temperature response element 34 drops below the trigger temperature. characterized in that it is configured to be able to
Temperature sensitive shut-off valve. In the temperature-sensitive shut-off valve (100),
characterized in that it is configured to enable remote monitoring of the TRSV (100) by providing an electrical output indicative of an “open” and “closed” state of the TRSV (100) by a sensor.
Temperature sensitive shut-off valve. According to claim 1,
The fourth open end (40) is characterized in that it comprises an alarm contact (61) for providing a signal when the TRSV (100) is activated.
Temperature sensitive shut-off valve. Temperature sensitive shutoff for fluid including housing 50 , first cap 12 , second cap 22 , third cap 32 , piston 42 , spring 44 and reset lever 46 . In the valve (100),
The housing (50) includes a first open end (10), a second open end (20), a third open end (30) and a fourth open end (40),
The first cap (12) is disposed on the first open end (10),
- at least one port serving as an inlet for a fluid sample; The inlet is connected to the chamber 51 and the chamber 52,
- a plug configured to move freely within the chamber (52) and to close the valve;
The second cap 22 is disposed on the second open end 20 of the housing 50,
- a shaft 24 arranged in the second cap and movable in the axial direction;
- a cam 26 connected to the shaft 24 on the inside of the housing 50 ; and
- a spring (22a) disposed in the cap (22);
The third cap 32 is disposed on the third open end 30 of the housing 50,
- a temperature responsive element 34 arranged in the cap 32 such that the flow of fluid passes through the temperature responsive element 34 before exiting through the outlet;
- a pin (36) disposed on the temperature-responsive element (34) to impart a stroke when the temperature of the fluid passing through the temperature-responsive element (34) rises and exceeds the trigger temperature; configured to adjust the gap between the shaft 24 and the pin 36 by
The piston 42 is disposed on the fourth open end 40 of the housing 50 , the piston 42 including a cam profile slot 42a, the piston having a bush 42b and a nut 42c at one end. ), guided by the pin 16 of the chamber 52 at the other end,
A spring 44 is disposed on the piston 42 such that the piston 42 is capable of axial movement within the housing 50 ,
The reset lever (46) is pivoted relative to the piston (42),
When the temperature of the fluid reaches the trigger temperature value, the pin 36 of the temperature response element 34 begins to push the screw 28 thereby moving the shaft 24 and compressing the reset spring 22a, and then the cam 26 guides the cam profile 42a of the piston 42, thereby pushing the piston 42 forward by the expansion of the spring 44, while the pin 16 pushes the ball 14 into the inlet characterized in that it is configured to close
Temperature sensitive shut-off valve.

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