KR101355773B1 - Apparatus for quenching specimen of jominy end quench test - Google Patents

Abstract

The present invention relates to a test device for cooling a hardenability test specimen, comprising: a housing portion configured to carry out a plurality of specimens heated in a heating furnace to be separated and stored through an internal partition space, and toward each of the specimen front ends separately stored in each partition space; And a coolant injection unit formed to inject coolant and a partition formed on a boundary line of the compartment space to prevent the coolant injected through the coolant injection unit from flowing out to the adjacent compartment.

Description

Hardness Test Specimen Cooler {APPARATUS FOR QUENCHING SPECIMEN OF JOMINY END QUENCH TEST}

The present invention relates to a test piece cooling apparatus capable of effectively spraying cooling water to simultaneously perform quenching from the tip side after heating a plurality of specimens simultaneously to evaluate the mechanical properties of the steel, particularly the hardenability.

In order to comprehensively determine the mechanical properties including the hardenability of the steel, a continuous cooling phase transformation diagram (CCT diagram) is used. However, it is difficult to prepare a corresponding continuous cooling phase transformation diagram for each product.

Considering this situation, a general method for evaluating the hardenability of steel is to test the hardenability by quenching one end of the heated steel (called 'jomini test'). have.

An object of the present invention is to provide a curing test specimen cooling device equipped with a cooling water spraying facility to perform the curing test for a plurality of specimens at the same time.

Another object of the present invention is to store a plurality of specimens taken out of the heating furnace into respective insertable compartments, and to form a cooling water spraying zone separated from each other so as to effectively quench the test specimens. In providing a device.

According to the spirit of the present invention, a housing portion provided to carry out a plurality of specimens heated in the heating furnace to be isolated and received through the partition space therein; A coolant spray unit configured to spray coolant toward each of the test piece front ends that is separately contained in the partition spaces; And forming a diaphragm on the boundary line of the compartment space to prevent the coolant injected through the coolant jetting unit from flowing out to the adjacent compartment.

The housing part may include an upper cover provided with a plurality of accommodation holes to drop through the plurality of specimens taken out of the heating furnace from the front end of the specimen.

The coolant spray unit may include a plurality of spray nozzles disposed through the lower portion of the housing part and configured to spray coolant toward a test piece front end portion separately contained in the partition space; Cooling water storage tank for storing the cooling water to be sprayed through the injection nozzle; A pump which draws the cooling water from the cooling water storage tank and supplies the cooling water to the injection nozzle through a pipe; And a valve provided on a pipe connected from the coolant storage tank to the injection nozzle to control the flow of the coolant.

The cooling water injection unit may further include a cooling control unit controlling an electric signal applied to the pump and the valve to adjust the flow rate and the hydraulic pressure of the cooling water injected through the injection nozzle.

The cooling water injection unit may further include an operation switch electrically connected to the cooling control unit so as to receive a command for cooling water injection from a user.

The cooling water leakage prevention unit, the diaphragm frame is formed on the boundary line of the partition space to form an outer frame of the diaphragm; And a diaphragm receptor interposed on the inner surface of the diaphragm frame to form a built-in surface of the diaphragm and preventing the coolant from flowing out through the partition space.

Here, the diaphragm receptor may be a micro transmission network in which a fine lattice hole is formed through the front surface so as to absorb the coolant generated in both directions based on the partition space.

According to the present invention, by providing a specimen cooling apparatus that can simultaneously perform a hardenability test for a plurality of specimens, there is an effect that can improve the test accuracy through the results of the hardenability test simultaneously measured for a plurality of specimens.

In addition, according to the present invention, by removing the plurality of specimens from the heating furnace, and using a structure that is isolated and stored in the compartment space to spray the cooling water, the leakage of the cooling water to the peripheral specimens (e.g., 튐 phenomenon) to prevent the test There is an effect that can improve the precision.

In addition, according to the present invention, the process of heating and cooling a plurality of specimens to proceed continuously, there is an effect that can reduce the time required for the test.

1 is a view showing a schematic configuration of a hardenability test specimen cooling apparatus according to an embodiment of the present invention.
2 is a view conceptually showing the detailed configuration of the coolant injection unit of the configuration of the test device for cooling the hardenability test specimen according to an embodiment of the present invention.
3 is a view schematically showing the shape and structure of the cooling water leakage prevention portion of the configuration of the test device for cooling the hardenability test specimen according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described with respect to the hardenability test specimen cooling apparatus according to a preferred embodiment of the present invention.

1 is a view showing a schematic configuration of a hardenability test specimen cooling apparatus according to an embodiment of the present invention.

In order to clearly understand the present invention conceptually, only FIG. 1 clearly clarifies only main features, and as a result, various modifications of the drawings are expected, and the scope of the present invention needs to be limited by the specific shapes shown in the drawings. There is no.

Referring to FIG. 1, the illustrated hardenability test specimen cooling device includes a housing part 110 for accommodating a plurality of heated specimens S, and a cooling water injection part for injecting cooling water into the specimens S. 150 and the cooling water leakage preventing unit 150.

The housing unit 110 is a cooling test case for carrying out a plurality of heated specimens S, isolating them once, and quenching them through the specimen tip portion Sa.

In particular, the present embodiment is not a method of evaluating the hardenability of one specimen (S), but simultaneously applied to a plurality of specimens (S), as shown in the plurality of specimens in the heating furnace (H). (S) is heated simultaneously.

However, it is shown here that three specimens S are simultaneously heated and cooled, but this is merely exemplary and the number of specimens S is not limited to the present invention.

The housing part 110 is disposed below the heating furnace H. This is to allow the plurality of specimens S, which have been heated in the heating furnace H, to be freely dropped to the housing part 110 at the same time as the mounting is released.

In particular, on the upper cover 112 of the housing 110 is provided with a receiving hole 113 formed in correspondence to the shape and size of each specimen. And the receiving hole 113 is preferably formed to be equal to the number of the plurality of specimens (S) heated simultaneously.

As a result, the plurality of specimens S, which have been heated in the heating furnace H, are freely dropped downward when the mounting is released, and are separately stored through the receiving hole 113 of the housing 110.

In addition, the housing 110 has an internal partition space R formed equal to the number of the receiving holes 113. Here, the partition space (R) means an isolation space formed at the lower side of each receiving hole 113, the cooling water outflow prevention portion 150 to be described later on the boundary is installed in the form of a diaphragm.

The shape and structure of the housing unit 110 having such a structure may be differently implemented and changed slightly depending on the number and size of the specimens S, as shown.

As described above, cooling is performed on the plurality of specimens S accommodated in the compartment space R inside the housing 110.

The cooling water injection unit 130 is cooling means for simultaneously cooling the plurality of specimens S isolated and stored for each of the partition spaces R in the housing unit 110. In particular, each of the partition space (R) may be formed to spray the cooling water (W) toward each specimen front end (Sa) housed separately.

Referring to FIG. 2 to look at the detailed configuration of the coolant injection unit 130. The cooling water injection unit 130 illustrated in FIG. 2 includes a detailed configuration of the injection nozzle 131, the cooling water storage tank 133, the pump 135, and the valve 137.

The injection nozzle 131 penetrates the lower part of the housing part 110, and is arranged in plurality. And it is formed so that the cooling water W may be sprayed toward the test piece front-end part Sa isolated by each compartment space R of the housing part 110. As shown in FIG.

The cooling water storage tank 133 stores the cooling water W to be injected through the injection nozzle 131. In addition, the coolant injection unit 130 includes a pump 135 and a plurality of valves 137.

The pump 135 is provided on the pipe 134 connected from the cooling water storage tank 133 to the injection nozzle 131. The cooling water W stored in the cooling water storage tank 133 is drawn out by the hydraulic pressure applied by the pump 135, and then injected into the specimen tip Sa through the injection nozzle 131 at an appropriate pressure.

The valve 137 may be installed on the pipe 134 connecting the pump 135 and the injection nozzle 131, respectively, to control the flow of the cooling water W injected through the injection nozzle 131. Adjust the opening and closing.

2, the pipe between the pump 135 and the valve 137 may be branched into three pipes, and one valve 137 may be installed for each branched pipe.

In addition, the cooling control unit 140 may be further configured in the cooling water injection unit 130.

The cooling controller 140 controls the electric signals applied to the pump 135 and the valve 137 to adjust the flow rate and the hydraulic pressure of the cooling water W injected through the injection nozzle 131. In charge.

The cooling control unit 140 may further include an operation switch 142.

The operation switch 142 is provided with a plurality of button-type or dial-type switches to receive a command from the operator, and converts the commanded signal into an electrical signal to facilitate the operation of the cooling control unit 140.

In addition, the cooling control unit 140 may further include a display device configured to enable two-way communication and notify the operator of the response to the command signal as visual information.

The cooling water leakage preventing unit 150 forms a diaphragm on the boundary line of the compartment space R inside the housing 110, and the cooling water W injected through the cooling water injection unit 130 flows out into the adjacent compartment. It plays a role in preventing it from becoming.

In other words, the cooling water outflow prevention part 15 has the specimen S housed in the adjacent compartment space R so that the cooling water W is injected only to the specimen tip portion Sa accommodated in the compartment space R. The cooling water (W) is prevented from flowing out to the side.

In particular, after the cooling water W injected at a predetermined pressure is discharged toward the test piece front end Sa, a phenomenon in which the cooling water W splashes in both sides may occur. The water droplets of the cooling water (W) protruding like this come into contact with the side of the specimen (S) stored in the vicinity, which hinders the test accuracy.

Therefore, by forming one diaphragm on the boundary of each compartment space (R) of the housing 110, it is necessary to block the absorption of the coolant droplets splashing out in both directions, it is to implement this function is to prevent the coolant leakage 150 It is

Detailed configuration of the cooling water leakage prevention unit 150 can be confirmed through FIG.

Referring to FIG. 3, the illustrated coolant leakage preventing unit 150 includes a diaphragm frame 152 that forms an exterior frame and a diaphragm container 154 that forms an interior surface of the diaphragm frame 152.

The diaphragm frame 152 is a structural member that forms an exterior frame of the coolant leakage preventing unit 150 and is made of a material that secures the rigidity enough to maintain its installation position and posture against the force impinged by the coolant droplets. It is preferable.

1 and 2, the diaphragm frame 152 is installed on the boundary line of the partition space R, and a plurality of the diaphragm frames 152 are provided inside the housing.

The diaphragm receptor 154 is interposed in a plane shape inside the diaphragm frame 152 to form a visceral surface.

As a specific example of such a diaphragm receptor 154, a material capable of absorbing coolant generated in both directions may be used, and further, a micro transmission network in which a fine lattice hole h is formed through the front surface may be used. Here, the fine lattice hole h preferably has a smaller cross section than the average particle diameter of the cooling water droplets.

Hereinafter, the operation and effect of the curable test specimen cooling apparatus according to the present invention will be described with reference to FIG.

First, when the plurality of specimens S that have been heated in the heating furnace H are released from the heating furnace, the specimen front end Sa is received through the housing 110 provided on the lower side. Towards Sa, the cooling water injection unit 130 injects the cooling water, and at this time, by controlling the proper flow rate and hydraulic pressure of the cooling water to be injected by the cooling control unit 140, the pump 135 in the cooling water injection unit 130 and The driving of the valve 137 is regulated.

On the other hand, the cooling water injected during the cooling process for the plurality of specimens (S) in the plurality of compartments (R) may be discharged in both directions, the cooling water flowing out through the cooling water leakage prevention unit 150 Block absorption. As a result, several specimens S can be heated simultaneously, and these specimens S can be cooled simultaneously from a front end side. As a result, evaluation of the curing performance of the plurality of specimens S can be simultaneously performed, and the average value thereof can be obtained, thereby improving the accuracy of the test.

As described above, according to the hardening test specimen cooling device according to the present invention, by providing a test piece cooling device capable of simultaneously performing a hardenability test for a plurality of specimens, the results of the hardenability test measured for each of a plurality of specimens Can be evaluated on average to improve test accuracy.

In addition, by taking out a plurality of specimens from a heating furnace, storing them separately in a compartment, and then independently spraying the cooling water, it is possible to prevent leakage of the cooling water to surrounding specimens, in particular splashing, to improve test accuracy. Can be.

Furthermore, according to the hardenability test specimen cooling apparatus according to the present invention, after simultaneously heating a plurality of specimens at a time, the cooling process can be carried out continuously at the same time, thereby reducing the time required for the hardenability test Has an effect.

In the above, the hardenability test specimen cooling apparatus according to the present invention has been described.

It is to be understood that the foregoing embodiments are illustrative in all respects and not restrictive, the scope of the invention being indicated by the following claims rather than the foregoing description.

Furthermore, all changes or modifications derived from the meaning and scope of the claims to be described below and equivalent concepts thereof should be construed as being included in the scope of the present invention.

H: furnace
S: The Psalms
110: Housing
130: coolant injection unit
150: cooling water leakage prevention unit

Claims (7)

A housing part provided to carry out a plurality of specimens heated in a heating furnace and to be separately accommodated through a partition space therein;
A coolant spray unit configured to spray coolant toward each of the test piece front ends that is separately contained in the partition spaces; And
Forming a diaphragm on the boundary of the compartment space, the cooling water outflow prevention unit having a fine permeation network to prevent the coolant injected through the coolant injection unit flows into the adjacent compartment space; Hardness test specimen cooling device comprising a.
The method of claim 1,
The housing part,
And a top cover provided with a plurality of receiving holes to drop the plurality of specimens carried out from the heating furnace from the specimen tip and penetrate them.
The method of claim 1,
The cooling water jetting unit includes:
A plurality of injection nozzles disposed through the lower portion of the housing part and configured to spray cooling water toward a test piece front end portion separately contained in the partition space;
Cooling water storage tank for storing the cooling water to be sprayed through the injection nozzle;
A pump which draws the cooling water from the cooling water storage tank and supplies the cooling water to the injection nozzle through a pipe; And
And a valve provided on a pipe connected from the cooling water storage tank to the injection nozzle, the valve configured to control the flow of the cooling water.
The method of claim 3, wherein
The cooling water jetting unit includes:
And a cooling control unit for controlling an electric signal applied to the pump and the valve to adjust the flow rate and the hydraulic pressure of the cooling water injected through the injection nozzle.
5. The method of claim 4,
The cooling water jetting unit includes:
And a control switch electrically connected to the cooling control unit to receive a command for cooling water injection from a user.
The method of claim 1,
The cooling water leakage prevention unit,
A diaphragm frame formed on a boundary line of the partition space to form an outer frame of the diaphragm; And
Includes a diaphragm interposed on the inside of the diaphragm frame to form a built-in surface of the diaphragm, and prevents the coolant from flowing out through the compartment space;
The diaphragm receptor is a test piece cooling device, characterized in that the fine permeable network.
The method according to claim 6,
The diaphragm receptor,
And a fine lattice hole is formed through the front surface so as to absorb the coolant generated in both directions with respect to the partition space.

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