KR101927781B1 - Tester for unexploded type fixed temperature heat detector - Google Patents

Abstract

The present invention provides a heat exchanger comprising a casing part (130) having an open upper part and a control line connected thereto, a heat transfer part (120) having a lower side inserted into the casing part and an inserting part to insert a sensing part of the sensor, A coil part 160 coupled to the insertion part and generating heat in accordance with the control power, a coil part 160 housed in the insertion part and arranged to surround an outer surface of the sensing part, And a heat transfer medium (150) for transferring the heat generated by the heat transfer medium to the sensing unit in a conductive manner. Thus, accurate set temperature can be delivered at the correct location, which improves the accuracy of the test in a warm temperature sensor.

Description

TECHNICAL FIELD [0001] The present invention relates to a tester for an explosion-proof type sensor,

The present invention relates to a tester for a warm-air-type sensor, and more particularly, to a warm-temperature type explosion-proof sensor tester capable of precisely testing the performance of a sensor installed in a building structure such as a ceiling or a wall.

Generally, various detectors installed on a building structure such as a ceiling or a wall are a kind of disaster prevention or fire fighting equipment, and their performance should be kept constant so that they can be notified by fire or lightning when a fire or the like occurs.

Such fire detectors are required to satisfy the regulations of the Ministry of Emergency Management and Emergency Management of the Republic of Korea at the time of manufacture, type approval, use and installation, and fire detectors are typically used to detect smoke smoke and fire heat And the sensation of heat sensation. It is also classified into a spot-type sensor that detects the local portion and a distributed-type sensor that detects the entire area according to the sensing method.

The type of the sensor is classified into a differential type, a differential type, a differential type, a spot type, a warm temperature type, a temperature sensing type, a linear type, an ionization type, a photoelectric type, a thermal hybrid type, a smoke composite type, .

The smoke detector is a device that detects smoke by detecting an accident. Ion type detectors and photoelectric detectors are widely used. Constant temperature type fire detectors operate when they are above a certain temperature, A bimetallic type sensor that uses a bimetal thermal deformation to move a contact using a contact, and a sensing line where two separated sensing lines come in contact with each other under predetermined conditions.

These fire detectors must alarm the fire when a smoke concentration above a predetermined level is sensed or a heat above a reference value is detected. If the fire detector is malfunctioning below the reference value, it may cause confusion if there is no fire, It can be misleading and cause a major accident.

Therefore, there is a continuing demand for development of a fire detector tester which can test whether the fire detector installed in each location is operating correctly.

Open Utility Model No. 1999-0033165 discloses a portable fire detector tester of the prior art, and Fig. 1 is a front view thereof.

In detail, a socket 24 is formed in the housing 22 so as to install a halogen lamp or the like 36, a heat plate 26 is formed on the inner surface of the housing 22, It maintains heat. In this way, the normal temperature operation can be tested by raising the temperature sensor to a predetermined temperature through heat generated by halogen or the like.

However, when the test is performed on the conventional warm-up type and / or explosion-proof type detectors, the temperature changes according to the distance between the testing device and the fire detector or the flow environment condition of the air, Since a malfunction can be prevented as a fire detector by precisely controlling a predetermined reference temperature, a tester must also be able to confirm whether or not the reference value is accurately met. However, there is no such measure yet.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a constant temperature type explosion-proof detector tester capable of testing an operation according to an accurate temperature of a warm temperature sensor.

The present invention provides a heat exchanger comprising a casing part (130) having an open upper part and a control line connected thereto, a heat transfer part (120) having a lower side inserted into the casing part and an inserting part to insert a sensing part of the sensor, A coil part 160 coupled to the inserting part and generating heat in accordance with control power, and a coil part 160 housed in the inserting part and raised in water level by inserting the sensing part, And a heat transfer medium (150) which is arranged to surround the outer surface of the part and conducts heat generated in the coil part to the sensing part in a conductive manner. Thus, accurate set temperature can be delivered at the correct location, which improves the accuracy of the test in a warm temperature sensor.

Preferably, the casing portion has a step portion on which a step of the heat transfer portion and a lower end of the casing portion are seated.

The cover portion may be formed of a transparent material so as to identify the position of the sensor, and may function to determine the depth of the sensing portion, which is inserted into the insertion portion, with the top thereof contacting the ceiling surface.

The heat transfer part may have a guide surface formed to guide the insertion of the sensing part toward the insertion part.

The heat transfer medium may be composed of dimethylpolysiloxane silicone oil.

According to the present invention, it is possible to set and relate precisely to the sensor in various positions corresponding to various positions of the detector, and it is very effective in accurately setting the temperature during the test of the warm temperature sensor through application of coils, inserts, and heat transfer media. This contributes to improving the precision of the inspection for correct operation of the detector and also to ensure accuracy in fire prevention and surveillance.

1 is a front view of a prior art portable fire detector tester.
2 is a perspective view of a constant temperature type explosion-proof sensor tester according to the present invention.
3 is a front view of the constant temperature type explosion-proof sensor tester of FIG.
4 is a front cross-sectional view of a constant temperature type explosion-proof sensor tester according to a preferred embodiment of the present invention.
5 is a view for explaining the use state of the constant temperature explosion-proof type detector tester.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the following description, when a part is referred to as being 'connected' to another part, it includes not only a direct connection but also a case where another part or device is connected in between. In addition, when a part is referred to as including an element, it is to be understood that the element may include other elements, not the exclusion of any other element, unless specifically stated otherwise.

The present invention basically includes a casing unit for opening the upper part and connected to the control line, and a lower part inserted into the casing part and having an insertion part for inserting the sensing part of the sensor from the upper side And a cover portion coupled to the casing portion to be disposed on the outer side of the heat transfer portion.

As described above, in the case of the warm air sensor, the external conductor senses a change in temperature by opening / closing the contact point by using a feature of expanding or contracting in the longitudinal direction due to a change in the ambient temperature. Deformation occurs due to heat transfer from the sensing side and internal contacts are connected to generate a fire signal.

The explosion-proof type is a detector used mainly in the presence of an explosive substance such as a gas, which means that the gas or the like is prevented from intruding through the closed structure of the detector.

The present invention is basically applied to a constant temperature explosion-proof type sensor, but it does not exclude cases of non-explosion type, and various kinds of sensors in which a sensor in the form of a rod for predetermined contact operation is disposed And it is understood that it is included in the concept of the invention.

Such a constant-temperature type explosion-proof type detector is mainly disposed in a ceiling portion of a building, but the arrangement form such as a wall surface or a floor surface is not limited.

FIG. 2 is a perspective view of a constant temperature type explosion-proof sensor tester according to the present invention, and FIG. 3 is a front view of a constant temperature explosion-proof type sensor tester of FIG.

The casing unit 130 functions to support the cover unit 110 and the heat transfer unit 120 on the upper side and accommodates a control line capable of performing control of the heat generating function, Ensure accurate heat transfer. The casing part 130, the cover part 110 and the heat transfer part 120 may be regarded as constituting the head part 100 as a whole and a predetermined supporting or extending part capable of grasping and controlling can be further coupled . A detailed description related to the arrangement of the control lines and the support of the casing unit 130 will be described later.

The casing unit 130 may be formed of a selected material, and may be made of a metal such as aluminum to ensure durability and rigidity.

The casing unit 130 has a generally cylindrical shape and an opening at the upper side thereof is opened to support the cover unit 110 and the heat transfer unit 120 through a predetermined stepped portion.

A part of the heat transfer part 120 is inserted into the casing part 130 and a coil part capable of generating heat is coupled to the lower end part of the heat transfer part 120 to perform a function of transferring the heat set by the conduction method to the sensing part of the warmth type explosion- do. The construction of this coil part will be described later in the description of FIG.

The heat transfer part 120 may be configured to partially protrude upward while being coupled to the casing part 130. As described above, the heat transfer part 120 directly transfers heat to the constant temperature type explosion-proof type sensor. For this, the heat transfer part 120 may be made of a highly conductive metal material, and such material is optional.

The heat transfer part 120 is inserted into the inserting part 122 from the upper side to the lower side and a sensing part protruding downward from the constant temperature explosion-proof sensor is inserted into the inserting part 122. The inserting portion 122 may have a cylindrical shape with an open upper portion and a closed lower portion and a side wall, and a heat transfer medium is accommodated therein so that heat from the coil portion can be directly transmitted.

In order to test the performance of a conventional constant temperature type explosion-proof type detector, a flower source such as a lighter is adjacently disposed. In such a case, heat transfer is difficult due to heat transfer by radiation or convection. Especially, in the case of the temperature sensor, it is operated only at the set temperature. Therefore, it is very sensitive to check the operation at the set temperature. When the fire source is near, the temperature becomes excessively high and it is practically impossible to check whether the operation is performed at the set temperature there is a problem. In addition, since most of the detectors are arranged on the non-reachable portion such as the ceiling, it is difficult to set the exact position of the inspection devices. Even if the heating elements are adjoined to each other, There is a problem that the uniformity is not secured.

In order to solve such a problem, in the present invention, the heat transfer part 120 is provided with the insertion part 122 to insert the sensing part into the correct position, and the heat transfer medium is received in the insertion part 122, So that it can be uniformly performed.

That is, in the present invention, the inserting part 122 formed in the heat transfer part 120 inserts the sensing part at an accurate position and transmits heat through the heat transfer medium in a conductive manner. Therefore, And the uniform heat can be uniformly transmitted to the sensing unit, so that accuracy in the inspection of the warm-temperature explosion-proof sensor can be dramatically improved.

As described above, since the sensing part is formed of a long rod or a rod, there is a possibility that the inserting part 122 is not inserted smoothly. In order to guide the insertion of the sensing part, the upper side of the heat transfer part 120 adjacent to the insertion part 122 is formed to have a height lower than the center side, It is preferable that it is in the form of a photograph surface. Accordingly, the heat transfer part 120 may have a funnel shape as viewed from above.

The cover 110 covers the upper portion of the heat transfer unit 120 and is coupled to the upper end of the casing 130. 3, the upper end of the cover 110 may be disposed above the upper end of the heat transfer part 120. The upper end of the cover 110 may be spaced apart from the outer periphery of the heat transfer part 120 More preferable.

The cover 110 prevents unnecessary heat from being transmitted to the external structure or equipment by the heat transfer part 120 and protects the heat transfer part 120. When the cover part 110 operates on a detector installed on the ceiling, So that leakage of external heat can be prevented and an accurate positional relationship between the sensing unit and the heat transfer unit 120 can be set. To this end, it is preferable that the upper end side of the cover portion 110 is formed in a ring shape thicker than the side wall portion.

Meanwhile, since the cover 110 performs the function of guiding and protecting the heat transfer part 120 to the correct position as described above, the upper end is formed to have a larger diameter than at least the side where the upper end is coupled to the casing part 130 It is good. Therefore, as shown in the drawing, a predetermined step may be formed on the side coupled to the casing unit 130 so that the diameter is small in diameter and the diameter is large in the portion adjacent to the ceiling, and in some cases, it may have an inclined surface.

However, when the cover 110 forms an outer appearance and accommodates the heat transfer part 120 therein, it is difficult to clearly grasp the positional relationship between the heat transfer part 120 and the warm temperature explosion-proof type detector The cover 110 may be made of a transparent material and a synthetic resin material may be considered, but the present invention is not limited thereto.

The casing unit 130 may be coupled to the connection unit 142 so as to extend downward to be connected to a predetermined support member. The casing unit 130 or the head unit 100 may be coupled to the connection unit 142, And can be connected to the hinge 141 so as to be rotatable.

The connection part 142 is preferably formed in a U shape, but this shape is selectable.

A connector portion 143 is formed at a lower end of the connection portion 142 and at least one terminal capable of inputting control power may be disposed at the connector portion 143.

The control power input from the connector portion 143 passes through the inside of the connection portion 142 and is connected to the inside of the casing portion 130 through the hinge portion 141 and then to the coil portion coupled to the heat transfer portion 120 , And the connection of such control power is made up of a control line which is a predetermined conductor. Accordingly, the connection portion 142 may be formed in a hollow tube shape.

The hinge part 141, the connection part 142 and the connector part 143 can be seen as a support part 140 connecting the casing part 130 to the lower supporting part. In some cases, the head unit 100 may be operated independently without the supporting unit 140.

4 is a front cross-sectional view of a constant temperature type explosion-proof sensor tester according to a preferred embodiment of the present invention.

As described above, the casing unit 130 forms a space through which the control line 170 for communicating control power communicates whilst supporting the overall structure. As shown in the figure, the casing unit 130, the heat transfer unit 120, and the cover unit 110 may be formed in a symmetrical shape with a circular cross section as a whole, and the casing unit 130 may protrude in the outer circumferential direction, And the step portion 131 formed on the cover 120 and / or the cover portion 110 may have a stepped portion.

The lower end of the heat transfer part 120 is inserted into the opening of the casing part 130 and the step formed at a part of the side wall of the heat transfer part 120 is seated on the step part 131, And the casing unit 130 is wrapped around the outer casing so as to be brought into close contact with the step 131 at the lower end.

As described above, the heat transfer part 120 has a guide surface part 121 having an inclined surface from the upper side and a height lower toward the center side, and an insertion part 122 extending downward is formed at the center side thereof.

The insertion portion 122 protrudes downward from the overall structure of the heat transfer portion 120 and is coupled to the outer surface of the insertion portion 122 so as to surround the coil portion 160. At this time, the heat transfer medium 150 is accommodated in the inner space of the insertion part 122 as described above.

The coil section 160 may be formed of a material having high resistance and exothermicity and may be wound in a spiral shape on an outer surface of the insertion section 122 as a selected number of times, have.

The control line 170 may be connected to the connector portion 143 through the hinge portion 141 and the connection portion 142 from the inner space of the casing portion 130 as a preferred embodiment.

A portion of the control line 170 may be grounded at a portion of the casing 130 and may be formed at the bottom of the casing 130 as a ground line that branches from the control line 170, (Not shown in the figure) or the through hole, and then grounded.

In addition, in order to support the grounding line and to stably support the internal structure and to facilitate maintenance, the bottom plate 133 may further be disposed on the inner lower end side of the casing unit 130. The bottom plate 133 is preferably made of an insulating material, and may be formed in a disc shape that closes a part or all of the through holes.

When the control power corresponding to the set temperature, which is the operation reference of the predetermined sensor, is inputted through the control line 170, heat is generated from the coil part 160 and heat is transferred from the outer wall to the inner wall of the insertion part 122, Heat can be uniformly transferred to the sensing portion of the sensor through the heat transfer medium 150.

The heat transfer medium 150 is suitably a liquid material having high stability and thermal conductivity, and its chemical stability and ability to prevent dangerous polymerization reaction become important factors. Furthermore, since the outflow can be made through the inlet of the insertion portion 122, it is better that the material is harmless to the human body.

The heat transfer medium 150 may be silicone oil, and in some cases the application of a fluid having a predetermined viscosity or gel is optional.

Dimethylpolysiloxane silicone oil was selected in the test procedure of the present invention, and KF-96-10CS was used to investigate the above-mentioned required characteristics. In the case of dimethylsilicone oil, it is composed of heat-resistant siloxane bond (Si-O-Si) and organic methyl group. It shows different characteristics from general mineral oil or synthetic oil. It is colorless and odorless. Its flash point is 94 ℃ ~ 176 ℃ and evaporation and vapor pressure are negligible It was confirmed to be enough. A specific gravity of 0.94 to 25 ℃ standards, auto-ignition temperature is approximately 400 ℃, a viscosity of 10mm ² / s to 25 ℃ reference. As described above, it is stable in the steady state and the polymerization reaction is inhibited. When it is partially decomposed at 150 ° C or higher, a small amount of carbon compound is generated but it is not significant. However, the operating temperature of the constant temperature type explosion- It is confirmed that it is more suitable as the heat transfer medium of the present invention because it is set on the basis of approximately 70 deg. In addition, skin tests on rabbits showed no PII 0.23 irritation, and skin tests on guinea pigs showed no skin sensitization.

The level of water disposed in the insertion portion 122 of the heat transfer medium 150 may be determined by the volume of the distal end of the sensor inserted into the insertion portion 122.

5 is a view for explaining the use state of the constant temperature explosion-proof type detector tester.

As shown in the figure, the present invention is described based on the case where the CCF type explosion-proof type detector 101 is disposed on the ceiling surface. However, when the CCFL type detector 101 is disposed on a wall surface, a floor surface or an inclined surface, Will be apparent to those skilled in the art.

The fixed-temperature type explosion-proof type sensor 101 includes a sensing part 102 extending downward, and the testing device is lifted to bring the heat transfer part 120 and the sensing part 102 close to each other. When the sensing part 102 is guided to the center side along the guide surface part 121 provided on the heat transfer part 120 and inserted into the insertion part 122, the heat transfer medium 150 As shown in Fig.

The control line 170 supplies control power to the coil part 160 through the connector part 143 as described above. When the control power corresponding to the operation set temperature of the constant temperature type explosion-proof type sensor 101 is supplied The coil part 160 generates heat to heat the insertion part 122 of the heat transfer part 120 and heat the heat transfer medium 150 to transmit heat to the sensing part 102 in a conductive manner.

The height of the heat transfer medium 150 is increased according to the insertion of the sensing portion 102 and the initial amount of the heat transfer medium 150 is increased to a certain height of the guide surface portion 121 upon insertion of the sensing portion 102 So that it can be ascertained.

The support portion 140 may be connected to the downwardly extending pole portion 200 and the control line 170 may extend downwardly along the inner or outer periphery of the pole portion 200. [ It is preferable that the pole base 200 is formed in a shape that can be stretched to correspond to various heights.

A control unit 300 connected to the control unit 170 through the control line 170 may be disposed and the control unit 300 may be formed integrally or separately from the pole unit 200.

The control unit 300 may previously store or set a set temperature corresponding to the corresponding thermostatic explosion-proof type sensor 101 in order to supply the control power. In one embodiment, the control unit 300 may supply the control power corresponding to the set temperature to the coil part 160 ). At this time, the control power corresponding to the set temperature may be determined in advance by the resistance and area of the coil part 160, the conductivity of the insertion part 122 of the heat transfer part 120, and the thermal conductivity of the heat transfer medium 150.

In one embodiment, it is possible to confirm whether the sensor is timely operated by fixing the temperature to the set temperature. In another embodiment, the control power may be gradually increased to check whether the sensor is operating in the temperature raising process.

The temperature-sensitive explosion-proof type tester according to the present invention can accurately set the relationship with the detector in correspondence with various positions of the detector and can position the detector. By applying the coil, the inserting portion and the heat transfer medium, It is very effective for accurate setting. This contributes to improving the precision of the inspection for correct operation of the detector and also to ensure accuracy in fire prevention and surveillance.

In the foregoing, the present invention has been described in detail based on the embodiments and the accompanying drawings. However, the scope of the present invention is not limited by the above embodiments and drawings, and the scope of the present invention will be limited only by the content of the following claims.

100 ... Head part 101 ... Temperature type explosion-proof detector
102 ... sensing portion 110 ... cover portion
120 ... heat transfer portion 121 ... guiding surface portion
122 ... insertion portion 130 ... casing portion
131 ... stepped portion 132 ... casing body
133 ... bottom plate portion 140 ... support portion
141 ... hinge portion 142 ... connection portion
143 ... Connector part 150 ... Heat transfer medium
160 ... coil part 170 ... control line
200 ... Paul Loan 300 ... control donor

Claims (5)

A casing unit 130 having an upper portion opened and a control line connected thereto;
A heat transfer part 120 having an insertion part for inserting a lower part of the casing part and a sensing part protruding downward of the sensor;
A cover part 110 coupled to the casing part so as to be disposed on the outer side of the heat transfer part;
A coil part 160 coupled to the insertion part to generate heat according to control power; And
And a heat transfer medium (150) accommodated in the inserting portion and arranged to surround the outer periphery of the sensing portion by raising the water level according to the insertion of the sensing portion and transferring the heat generated in the coil portion to the sensing portion in a conductive manner evenly Detector tester.
The method according to claim 1,
The casing unit includes:
And a step portion on which the step of the heat transfer portion and the lower end of the casing portion are seated.
The method according to claim 1,
The cover portion
The sensor tester is made of a transparent material so as to be able to identify the position with the detector, and functions to determine the depth of the sensing part, which is inserted into the insertion part, with the upper end touching the ceiling scene.
The method of claim 3,
The heat-
And a guide surface formed to be lower in height toward the insertion part side to guide insertion of the sensing part.
The method according to claim 1,
Wherein the heat transfer medium comprises:
Dimethylpolysiloxane A silicone oil tester.

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