KR101084658B1 - A stand for condenser - Google Patents

Abstract

The present invention relates to a stand for a cooler.
According to the stand for a cooler according to the embodiment of the present invention, the pressurizing means can be formed in the upper rack on which the cooler is seated so that the cooler can be tightly adhered to the sample tube. There is an effect that can be prevented.

Description

Cooling stand {A stand for condenser}

The present invention relates to a stand for a cooler.

A condenser used in a laboratory or the like refers to equipment for liquefying a gas generated from a chemical reaction or by boiling a liquid and exchanging heat with a refrigerant.

In general, a flow path through which a coolant flows is formed in the cooler, and an inlet and an outlet of the flow path may be connected to a coolant supply means respectively provided outside of the cooler. The cooler may further include an inlet port through which gas to be cooled is introduced and a discharge port through which liquefied gas is discharged. The gas introduced into the cooler through the inlet is deprived of heat to the refrigerant flowing through the flow path, and when the temperature falls below the boiling point, it is liquefied and discharged to the outlet.

And, the liquid discharged from the cooler can be collected in the sample tube.

The gas introduced into the cooler may be a gas generated by a predetermined chemical reaction inside the sample tube. For example, a gas may be generated by reacting a predetermined sample (soil, food, etc.) with an acid (nitric acid, sulfuric acid), etc. in the sample tube, and the generated gas may be supplied to the cooler.

In particular, a reflux condenser can cool the gas generated in the sample tube and send it back to the sample tube. In detail, the discharge port of the reflux cooler is disposed to be in close contact with the sample tube, the gas generated in the sample tube may be introduced into the reflux cooler through the discharge port. At this time, the inlet of the reflux cooler may be shielded. The condensate, which has been cooled and condensed in the reflux condenser, is again introduced into the sample tube through the discharge port.

On the other hand, in order to obtain accurate experimental results, it is necessary to prevent the gas introduced into the cooler from flowing out. Therefore, the cooler and the sample tube must be closely connected to each other. That is, the discharge port and the inlet portion of the sample tube are preferably sealed so that no gas flows out. In general, the cooler and the sample tube are sealed by directly contacting the discharge port and the inlet portion of the sample tube.

The cooler may be used after being fixed by a fixing means such as a forceps to a manual stand provided with the sample tube on one side. In this case, a separate clamp may be further used to closely contact the cooler and the sample tube.

Recently, in order to liquefy gas more efficiently, a stand for coolers has been commercialized, provided with an upper rack capable of mounting a plurality of coolers and a lower rack capable of mounting a plurality of sample tubes corresponding thereto. The cooler is then in close contact with the sample tube only by its own load.

However, the above conventional technologies have the following problems.

The cooler is generally formed of glass or plastic material, and the cooler does not have a weight enough to be in close contact with the sample tube. Therefore, there is a problem in that gas flows out between the cooler and the sample tube.

In particular, when the sample tube is heated according to the purpose of the experiment, there is a problem that the outflow is further accelerated by increasing the gas pressure inside the sample tube.

In addition, when the sample tube is heated, there is a problem that it is very dangerous because the experimenter has to manually move the lower rack or the sample tube of high temperature manually.

In addition, when the experiment is carried out using a plurality of coolers at the same time, there is a problem that it is difficult to check the state of the cooler located inside the upper rack.

The present invention has been proposed to solve the above problems, and an object of the present invention is to provide a stand for a cooler in which the coupling between the cooler and the sample tube can be maintained closely.

In addition, even if the experiment using a plurality of coolers and sample tubes at the same time, it is an object of the present invention to provide a stand for the cooler that can easily check each state.

In addition, an object of the present invention is to provide a stand for a cooler that can be safely used by an experimenter.

In the stand for the cooler according to the embodiment of the present invention for achieving the above object, at least one cooler is placed; A cover provided on one side of the first rack and provided with an elastic member for pressing the cooler; A second rack provided in the other direction of the first rack, in which at least one sample tube is placed in selective contact with the cooler; And a moving part for moving the first rack in the second rack direction, wherein the sample tube is formed to seal around the condensate outlet of the cooler, and the elastic member pressurizes the cooler toward the sample tube. It is characterized in that it is provided to.

The elastic member may be provided to be deformed according to the movement of the first rack after the cooler contacts the sample tube.

In addition, it characterized in that it further comprises a heating unit for heating the sample tube.

In addition, the cooler includes a locking portion mounted to the first rack, the elastic member is characterized in that for pressing the locking portion.

In addition, the cover is fixed to the first rack, characterized in that the movement with the first rack.

In addition, the cover includes an elastic member receiving portion for receiving the elastic member, characterized in that the engaging portion for mounting the cooler to the first rack is characterized in that moved inside the elastic member receiving portion.

In addition, the operation unit for operating the moving unit is characterized in that it is further included.

In addition, the moving part, the first rack is fixed, the support portion for reciprocating in one direction; A guide part for guiding a reciprocating motion of the support part; And a driving unit providing a driving force for moving the support unit.

In addition, the guide portion is characterized in that it is disposed on the rear side of the first rack and the second rack.

In addition, the cooler is characterized in that the reflux cooler.

In another aspect, a stand for a cooler according to an embodiment of the present invention, the case; A support part provided to be reciprocated in the vertical direction and including an arm extending forward of the case; A guide part for guiding the movement of the support part; An upper rack detachably coupled to the arm and configured to seat a catch of the cooler; A cover coupled to an upper side of the upper rack and having an insertion portion into which the cooler is fitted; An elastic member mounted to the insertion part to press the locking part; And a lower rack on which a sample tube for collecting condensate formed in the cooler is seated, wherein the lower rack is disposed such that the cooler and the sample tube selectively contact with the movement of the support, and the elastic member covers the cover. It is characterized in that it is provided to be compressed by the engaging portion in accordance with the movement of.

In addition, the guide portion is formed inside the case, and the arm is characterized in that it is exposed to the outside of the case.

In addition, the driving unit for providing a driving force for moving the support portion is further included, the guide portion includes a worm gear rotated by a motor included in the drive portion, the rear of the support portion is formed with a rack interlocked with the worm gear It is characterized by.

In addition, the cover is characterized in that coupled to the upper rack after the cooler is seated in the upper rack.

In addition, the heater for heating the sample tube is characterized in that it is further included.

In addition, the elastic member is provided with a compression spring, the cooler is characterized in that inserted into the compression spring.

In addition, the locking portion is characterized in that moved in the insertion portion.

In addition, the condensate discharge port of the cooler is characterized in that formed in the contact with the sample tube.

In addition, the elastic member is characterized in that the displacement is increased as the upper rack closer to the lower rack after the cooler is in contact with the sample tube.

According to the stand for a cooler according to the embodiment of the present invention as described above, by forming a pressurizing means in the upper rack on which the cooler is seated, the cooler can be tightly adhered to the sample tube, so that gas is transferred between the cooler and the sample tube. There is an effect that can be prevented from leaking.

In addition, by arranging the moving unit for moving the upper rack to the rear of the cooler and the sample tube, even if using a plurality of coolers and sample tubes at the same time, there is an advantage that it is easy to check each experimental state from the side .

In addition, in the case of the experiment for heating the sample tube, after the end of the experiment by moving the lower rack with the upper rack to cool the sample tube in the air quickly, the effect that the experimenter can perform the experiment more safely have.

1 is a perspective view showing the appearance of a stand for a cooler according to an embodiment of the present invention.
2 is a front view of the stand for the cooler of FIG.
3 is a perspective view showing the upper rack and the lower rack and the case removed from the stand for the cooler of FIG.
Figure 4 is an exploded perspective view showing the upper rack and the cover is coupled to the support.
5a to 5c is a view showing a state in which the cooler is pressed in accordance with the movement of the support.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a perspective view showing the appearance of a stand for a cooler according to an embodiment of the present invention, FIG. 2 is a front view of the stand for the cooler of FIG. 1, and FIG. 3 is an upper rack and a lower rack and a case in the stand for the cooler of FIG. 1. Is a perspective view showing the appearance removed.

In the present embodiment, for convenience of description, a view showing a state where one cooler and a sample tube are provided is used, but the spirit of the present invention is not limited to the number of coolers and sample tubes.

1 to 3, a stand 1 for a cooler according to an embodiment of the present invention includes a main body 10, a heater 20, and a cooler 60 provided on one side of the main body 10. Losing the first rack 40, the second rack 50, the sample tube 70 is placed, the moving part 30 for moving the first rack 40, and one side of the first rack 40 It may include a cover 80 provided to press the cooler 60 to be in close contact with the sample tube (70).

The main body 10 may be formed in a box shape having a substantially rectangular parallelepiped shape extending in one direction, and may include a case 11 for protecting the components provided therein. Slots 13 may be formed at both side surfaces of the case 11 to move the support part 31 to be described later.

In the present embodiment, the main body 10 is formed long in the vertical direction, the slot 13 also will be described as an example that is formed long in the vertical direction so that the support portion 31 can be moved linearly in the vertical direction.

In addition, an operation unit 15 for operating the moving unit 30 may be provided at one side of the case 11. The operation unit 15 may be connected to the driving unit 35 to be described later, and move the first rack 40 upward or downward according to a user's operation.

The heating unit 20 may include a heater 21 for heating the sample tube 70 to a predetermined temperature or more, and may be mounted at the lower end of the case 11. A plurality of sample tube inserting grooves 22 may be formed in the heater 21 so that the plurality of sample tubes 70 may be inserted therein.

The second rack 50 is disposed above the heating unit 20.

The sample rack 70 is disposed in the second rack 50 to collect the condensate discharged from the cooler 70 or to generate a reaction in which gas is generated.

In the second rack 50, the sample tube hanger 51, on which the sample tube 70 is placed, extends downward from the sample tube hanger 51 to support the sample tube hanger 51. A second rack leg 53 and a second rack handle 55 protruding from both sides of the sample tube hanger 51 may be included.

The second rack leg 53 may be placed on the bottom surface, and the sample tube hook portion 51 may be formed to be parallel to the ground.

In addition, the sample tube hanger 51 may be further formed with a second rack seating portion 52 seated on the heating unit 20 so that the second rack 50 can be placed in place.

The sample tube hanger 51 may be formed in a plate shape having a plurality of holes 511 through which the sample tube 70 may pass. The hole 511 formed in the sample tube hanger 51 corresponds to the position of the sample tube insertion groove 22 and is formed to correspond to the position of the cooler through hole 411 to be described later.

Both ends of the sample tube hanger 51 may be bent upward to extend, and a hook 513 may be formed at the extended portion to selectively couple with the first rack 40. The hook 513 may be fitted into the hook groove 431 to be described later as the first rack 40 moves.

The sample tube hanger 51 may be formed of a material that is elastically deformable for hooking metal, plastic, or the like.

The sample tube 70 is provided in the form of a container having a predetermined shape capable of accommodating liquid. In this embodiment, a sample tube 70 having a test tube shape having an upper end portion formed in a hemispherical shape will be described as an example.

The sample tube 70 forms a cylindrical sample tube body 71 capable of storing liquid, an upper opening of the sample tube body 71, and allows the lower end of the cooler 60 to enter a predetermined depth. The sample tube inlet 72 is formed to correspond to the shape of the lower end of the cooler 60, and is provided in a substantially central portion of the sample tube body 71 and protrudes in a band form along the outer periphery of the sample tube body 71. Sample tube catching portion 73 may be included.

The diameter of the hole formed in the sample tube hanger 51 is larger than the diameter of the sample tube body 71 and smaller than the diameter of the sample tube hanger 73. Accordingly, when the sample tube 70 is inserted from the upper side of the sample tube hanger 51, the sample tube catcher 73 may be caught by the sample tube hanger 51.

The sample tube 70 is placed in the second rack 50 with the second rack 50 removed from the stand 1 for the cooler, and then the stand for the cooler together with the second rack 50. It may be arranged in (1), or may be attached to the second rack 50 after the second rack 50 is disposed on the stand 1 for the cooler. At this time, the sample tube 70 is fitted to the second rack 50 and the heater 21 to form a state perpendicular to the ground.

Here, the second rack 50 is provided below the cooler stand 1, and may be referred to as a lower rack.

The first rack 40 is provided with the cooler 60 to condense the gas supplied from the outside into a liquid.

The first rack 40, the cooler hanger 41, the cooler hanger 41 is placed on the lower side of the cooler hanger 41, the vertical holding to maintain the vertical state of the cooler 60 A part 42, a side frame 43 for connecting the cooler hanger part 41 and the vertical holding part 43, extends laterally from the side frame 43 and is mounted on the support part 31 which will be described later. The rack mounting portion 44, and the cover fastening boss 46 for guiding the cover 80 can be coupled in place may be included.

The cooler hanger part 41 is provided with a plurality of cooler through-holes 411 through which the cooler 60 can pass. The cooler through hole 411 is formed at a position corresponding to the hole 511 formed in the sample tube insertion groove 52 and the sample tube hanger 51. In addition, the cooler through hole 411 is formed to a diameter smaller than the cooler catching portion 69 so that the cooler catching portion 69 to be described later.

A hole 421 corresponding to the cooler through hole 411 is also formed in the vertical holder 42. Since the cooler 60 is inserted into the cooler through-holes 411 and 421, fluctuations in the lateral direction can be prevented and the vertical state can be maintained.

Holes 411 and 421 through which the cooler 60 formed in the first rack 40 passes, holes 511 through which the sample tube 70 formed in the second rack 50 passes, and The sample tube insertion grooves 52 may be formed to be concentric with each other. Therefore, the cooler 60 may contact the sample tube 70 provided below through the first rack 40.

The cooler hanger 41 and the vertical retainer 42 are preferably provided in parallel with the ground and the sample tube hanger 51.

The outer side of the side frame 43 is provided with a first rack handle 47 protruding a predetermined length, it is provided so that the user can conveniently move the first rack 40.

In addition, a hook groove 431 may be formed at the lower end of the side frame 43 to correspond to the position and size of the hook 513. When the first rack 40 is moved below a predetermined distance, the hook 513 may be fitted into the hook groove 431.

In this example, the hook is formed in the second rack 50, the hook groove is described as an example formed in the first rack 40, but this is only one example, may be formed by changing the position of each other And other known optional coupling means such as magnets may be used.

The first rack seating part 44 is seated on the support part 31 so that the first rack 40 can be moved up and down with the support part 31, and the support part 31 is secured by a bolt or the like. It can be fixed to.

In addition, the first rack seating portion 44 may further be formed with a first rack guide 45 extending downward of the first rack seating portion 44 and in close contact with the side surfaces of the support part 31. . The first rack guide 45 is positioned such that when the first rack 40 is placed on the support 31, the cooler 60 is positioned at the correct position to be fitted to the sample tube 70. 1 may guide the coupling of the rack (40).

The cover fastening boss 46 may be formed at each corner portion of the cooler hanger 61, and protrudes upwardly so that the cover fastening boss 46 may be inserted into the cover fastening hole 811 formed in the cover 80. In addition, a fastening hole into which a predetermined fastening member may be inserted may be formed at an upper end of the cover fastening boss 46.

The cooler 60 is a device for condensing a liquid supplied by exchanging a gas supplied from the outside with a refrigerant, and a reflux cooler, a screw tube cooler, an old tube cooler, a straight tube cooler, and the like may be used.

In this embodiment, a reflux cooler is provided to the cooler 60 as an example.

The cooler 60 includes a cooler body 61 through which gas passes, a gas inlet 66 provided at an upper side of the cooler body 61, and a condensate in which gas is condensed, formed at a lower side of the cooler body 61. Condensate discharge port 62 discharged, a cooling passage 63 formed in the cooler body 61, a refrigerant inlet 64 and an outlet 65 connected to the cooling passage 63, and the cooler body ( A cooler catching portion 69 provided at an approximately central portion of the cooler 61 and protruding in a strip shape along the outer circumference of the cooler body 61 may be included.

The cooler body 61 may be formed as a cylindrical tube, and the length of the cooler 60 is long enough to contact the sample tube 70 with the movement of the first rack 40. do.

The gas inlet 66 may be formed at an upper end of the cooler body 61 and sucks gas to be condensed. For example, the gas inlet 66 may be connected to a reaction chamber (not shown) or an evaporation chamber (not shown) provided outside to suck the reaction gas. Alternatively, when the sample tube 70 is used as the reaction chamber, the gas inlet 66 may be shielded.

The discharge port 62 is preferably formed at the lower end of the cooler body 61 so that the condensate can fall by gravity. In addition, the periphery of the discharge port 62 is formed to correspond to the shape of the sample tube inlet 72 so that the cooler 60 is tightly contacted with the sample tube inlet 72 when the cooler 60 is moved downward. Can be.

The cooling passage 63 may be spirally formed to increase the heat exchange area, and may extend from an upper side to a lower side of the cooler body 61.

The coolant inlet 64 and the outlet 65 may be installed above the cooler body 61 to facilitate connection with a coolant supply means (not shown) provided to the outside.

The refrigerant introduced into the refrigerant inlet 64 passes through the cooling passage 63, takes heat from the gas, condenses the gas, and is discharged to the refrigerant outlet 65. As the refrigerant, a liquid having a temperature lower than the boiling point of the gas to be condensed is used. For example, water at room temperature may be used.

In addition, the cooler engaging portion 69 is formed to have a size larger than the diameter of the cooler through hole 411 so that the cooler 60 can be mounted on the first rack 40. Therefore, when the cooler 60 is inserted from the upper side of the cooler hanger 41, the cooler hanger 69 may be caught by the cooler hanger 41.

Meanwhile, the sample tube catching portion 73 and the cooler catching portion 69 may have a shape in which the sample tube 70 and the cooler 60 may be seated on the catching portions 51 and 41. It is not limited to the strip form.

The locked state of the cooler 60 may be released as the cooler 60 interferes with the sample tube 70 as the first rack 40 moves downward. Detailed information related to this will be described later.

The cooler 60 is placed in the first rack 40 in a state where the first rack 40 is removed from the stand 1 for the cooler, and then the stand for the cooler together with the first rack 40 ( It may be arranged in 1), it may be placed in the first rack 40 after the first rack 40 is disposed on the cooler stand (1).

In addition, the cooler 60 is disposed side by side with the sample tube 70 to be seated on the sample tube 70 during movement.

Here, the first rack 40 is provided on the upper side of the stand 1 for the cooler, may be referred to as an upper rack.

On the other hand, the cover 80 is fixedly mounted on the upper side of the first rack 40.

In detail, the cover 80 is mounted to the cover body 81, the cooler insertion hole 82, the elastic member receiving part 83, and the elastic member receiving part 83 formed in the cover body 81. An elastic member 85 for pressing the cooler 60 may be included.

The cover body 81 may be formed in a substantially rectangular parallelepiped shape and may correspond to the size of the cooler hanger 61. A cover fastening hole 811 into which the cover fastening boss 46 is inserted may be formed at an edge of the cover body 81.

In addition, the cover body 81 may be formed of a transparent material so as to check the degree of compression of the elastic member (85).

The cover fastening boss 46 may be inserted into the cover fastening hole 811 to be exposed to the upper portion of the cover body 81, and a fastening member such as a bolt may be coupled to the cover fastening boss 46. The upper end of the fastening member coupled to the cover fastening boss 46 may be formed larger than the diameter of the cover fastening hole 811 so that the cover body 81 does not fall after the fastening member is coupled.

However, the coupling method of the cover 80 is just an example, and the embodiments may be added, changed, or deleted within the scope of the spirit of the present invention.

The cooler insertion hole 82 may be disposed upward and downward to correspond to the position of the cooler through hole 411 so that the cover 80 may be fitted from above the first rack 40 in which the cooler 60 is placed. Perforations in the direction may be formed. In addition, the cooler insertion hole 82 has a width of at least the refrigerant inlet 64 and the outlet 65 so as not to interfere with the cooler 60 when the cover 80 and the first rack 40 are coupled to each other. It is formed more widely.

The elastic member accommodating part 83 may be formed to be connected to the cooler insertion hole 82 and may be formed in a groove shape recessed to a predetermined depth from a lower side of the cover body 81. The depth of the elastic member accommodating portion 83 is preferably formed to a sufficient depth so that the cooler engaging portion 69 can be moved a predetermined length therein. For example, the depth of the elastic member accommodating part 83 may be formed to correspond to the sum of the height of the cooler catching part 69 and the length before deformation of the elastic member 85.

In addition, the elastic member receiving portion 83 is formed in a size larger than the diameter of the cooler insertion hole 82, in particular, is formed in a size larger than the diameter of the cooler engaging portion (69). Therefore, the cooler catching part 69 may be accommodated inside the elastic member accommodating part 83.

In other words, the cooler insertion hole 82 and the elastic member accommodating portion 83 form one hole, and the boundary between the cooler insertion hole 82 and the elastic member accommodating portion 83 is formed to be stepped. Can be.

Here, the cooler insertion hole 82 and the elastic member accommodating part 83 may be referred to as a cooler insertion part, which is a part into which the cooler 60 is inserted.

One side of the elastic member 85 may be mounted on the ceiling surface of the elastic member receiving portion 83, the other side may be in contact with the upper side of the cooler engaging portion (69). That is, the elastic member 85 may be mounted in a form that can press the cooler catching portion 69 downward.

In the present embodiment will be described as an example that the cylindrical compression spring is provided to the elastic member (85). In this case, the diameter of the elastic member 85 may be larger than the diameter of the cooler body 61 and smaller than the diameter of the cooler catching portion 69 so as to pressurize the cooler catching portion 69. have.

The process of pressurizing the cooler 60 by the elastic member 85 will be described later with reference to the drawings.

The moving part 30 provides a support part 31 for supporting the first rack 40, a guide part 33 for guiding the movement of the support part 31, and a driving force for moving the support part 31. The driving unit 35 may be included.

The guide part 33 is provided inside the case 11, and includes a guide bar 331 extending from the bottom part 111 of the case 11 to the ceiling part 113, and a worm gear 333. can do.

The guide bar 331 may be formed perpendicular to the bottom portion 111 so that the support portion 31 can be moved in the vertical direction, and may be provided in the form of a cylindrical bar.

The driving part 35 is mounted to the bottom part 111 and is provided at the rear of the heating part 20. The driving unit 35 may include a driving motor (not shown), and a rotation shaft of the driving motor (not shown) may be connected to the worm gear 333 to rotate the worm gear 333.

The worm gear 333 may be formed in parallel with the guide bar 331, and may extend from the driving part 35 to the ceiling part 113. In addition, the worm gear 333 may be provided on the rear side than the guide bar 331.

The support part 31 includes a support body 311 into which the guide bar 331 is fitted, a support arm 313 extending vertically bent forward from both sides of the support body 311, and the support body 311. And a rack 317 interlocked with the worm gear 333.

A guide bar insertion hole 315 is formed in the support part body 311, and the guide bar 331 is fitted into the guide bar insertion hole 315. Thus, the support body 311 may be moved in the vertical direction along the guide bar 331.

The support arm 313 is exposed to the outside of the case 11 and extends forward, and the first rack 40 is seated in a portion exposed to the front of the case 11.

A fastening hole 319 is formed in the support arm 313, and the first rack 40 may be fixed to the support arm 313 by a fastening member such as a bolt.

The rack 317 is formed to be in contact with the worm gear 333 to be interlocked, and transfers the driving force provided from the drive motor (not shown) to the worm gear 333 to the support body 311 to support the support 31. ) Moves up and down. In detail, when the worm gear 333 is rotated in one direction, the support part 31 may ascend (or descend), and when the worm gear 333 is rotated in another direction, the support part 31 may descend (or ascend).

When the worm gear 333 is provided as a driving force transmission means as described above, there is an advantage that the amount of movement of the support 31 can be precisely adjusted.

However, as described above, the structure for moving the support part 31 is merely an example, and various techniques may be applied within a range in which the spirit of the present invention, such as a belt and a chain, is maintained.

In addition, in the present exemplary embodiment, the first rack 40 and the second rack 50 are disposed in the vertical direction, and the cooler 60 and the sample tube 70 are in contact with each other in the vertical direction. However, the spirit of the present invention is not limited thereto, and the embodiments may be added, changed, or deleted within the scope of the spirit of the present invention. For example, the racks 40 and 50 may be arranged in left and right or front and rear directions according to the shape of the cooler 60.

Hereinafter, the coupling of the first rack 40, the cover 80, and the support part 31 will be described with reference to the drawings.

Figure 4 is an exploded perspective view showing the upper rack and the cover coupled to the support.

Referring to FIG. 4, the first rack 40 may be coupled to the support arm 313 with the cooler 60 mounted thereon.

In this case, the cooler 60 may be spaced apart from the cooler hanger 41 by an external force applied from the lower side because the cooler catching part 69 is caught in the cooler hanger 41.

The first rack 40 is seated on the support part 31 so that the first rack guide 45 is in close contact with the inner side surface of the support arm 313. At this time, the fastening hole 441 formed in the first rack seating portion 44 and the fastening hole 319 of the support arm 313 are aligned, and then the first rack 40 is fastened with a fastening member such as a bolt. It is fixed to the support (31). Therefore, the first rack 40 may move in the up and down direction together with the support part 31.

In addition, the first rack 40 is seated on the support arm 313 which extends in front of the case 11 and is exposed, whereby the lateral space of the first rack 40 or the cooler 60 is Can be opened. Therefore, the experimenter can easily observe a state even if the cooler arrange | positioned at the rear side of the said 1st rack 40 in the side of the said cooler 60 is easy.

Then, the cover 80 is coupled to the first rack 40.

In detail, the cover 80 is coupled above the first rack 40 so that the cover fastening boss 46 is fitted into the cover fastening hole 811.

The cover 80 is coupled such that the bottom surface of the cover body 81 is in close contact with the top surface of the cooler hanger 41, and is fixed to the first rack 40 by a predetermined fastening member. The fastening member may be fitted to the cover fastening boss 46, and the head of the fastening member may be formed to have a size larger than the diameter of the cover fastening hole 811 so that the cover 80 does not move upward.

When the coupling of the cover 80 is completed, the cooler catching portion 69 is located inside the elastic member receiving portion 83, and the elastic member 85 is placed on the cooler catching portion 69. Can be contacted. Therefore, when an external force is applied to the cooler 60 from the lower direction, the elastic member 85 applies an elastic force to the cooler engaging portion 69 as a reaction against the external force.

Hereinafter, an example of a method of using the cooler stand 1 having the above configuration will be described.

The sample tube 70 is filled with a predetermined sample such as soil, food, and the like that react with the sample such as sulfuric acid and nitric acid. In this case, in order to promote the reaction, the sample tube 70 may be heated using the heating unit 20.

The second rack 50 on which the sample tube 70 is placed is arranged to allow the sample tube 70 to fit into the sample tube insertion groove 22.

Then, the cooler 60 is mounted on the first rack 40, and then the cover 80 is coupled. In this case, the gas inlet 66 may be shielded, and the refrigerant inlet 64 and the outlet 65 may be connected to the refrigerant supply means (not shown).

After coupling the first rack 40 to the support part 31, the user uses the operation part 15 to allow the cooler 60 to interfere with the sample tube 70 using the first rack 40. Descend until it no longer descends.

In addition, the user may further lower the first rack 40 until the hook 513 is coupled to the hook groove 431. In this case, coupling the hook 513 to the hook groove 431 may be selectively performed according to the type of experiment. For example, when the sample tube 70 is heated by the heating unit 20 as in the present embodiment, the hook 513 is coupled to the hook groove 431 to provide the first rack 40. At the time of raising), the second rack 50 may be raised together.

In this process, the cooler 60 is firmly adhered to the sample tube 70 by the elastic member 85. Detailed information related to this will be described later with reference to the drawings.

When the reaction is started by a predetermined action such as heating the sample tube 70, gas generated in the sample tube 70 flows into the cooler body 61 through the discharge port 62. .

The gas introduced from the sample tube 70 may be condensed by the refrigerant flowing through the cooling channel 63, and the condensate may be dropped by gravity and introduced into the sample tube 70 through the discharge port 62. .

When the reaction is completed, the user may raise the first rack 40 by using the operation unit 15 and collect the second rack 50.

In this case, when the first rack 40 and the second rack 50 are connected by the hook 513, the second rack 50 may be raised together with the first rack 40.

Thus, the second rack 50 is suspended in the air and the sample tube 70 is placed in the air. That is, the sample tube 70 may be cooled faster by air than when the sample tube 70 is plugged into the heating unit 20.

The user can safely cool the sample tube 70 in air without directly touching the sample tube 70 heated to a high temperature or the second rack 50 whose temperature is increased by heat transfer, thereby performing a safer experiment. can do.

When the cooling of the second rack 50 is completed, the user may apply a force to remove the hook 513 from the hook groove 431 and then collect the second rack 50.

The use method as described above is an example in which a reflux cooler is provided as the cooler 60, and may be used in other ways depending on the type of cooler or the purpose of the experiment.

For example, the sample tube 70 is used only for purely condensate, and the gas generated in a reaction chamber (not shown), which is provided separately to the cooler 60, is supplied to the gas inlet 66. May be

Hereinafter, referring to the drawings, the process of pressing the cooler 60 by the elastic member 85 as the first rack 40 descends will be described.

5A to 5C are views showing a state in which the cooler is pressurized as the support moves.

5A shows the cooler 60 before contacting the sample tube 70.

Referring to FIG. 5A, in a state in which the cover 80 is coupled to the first rack 40, the cover body 81 is in close contact with the upper surface of the cooler hanger 41. In addition, the cooler catching portion 69 may be accommodated inside the cooler inserting portions 82 and 83, and the elastic member 85 may contact the cooler catching portion 69.

In addition, the cooler 60 is disposed in parallel with the sample tube 70 so that the discharge port 62 can be accommodated in the sample tube inlet 72.

The cooler 60 is moved downward in contact with the movement of the support part 31 to contact the sample tube 70. The user may move the support part 31 in the vertical direction by using the operation part 15.

In addition, the cooler 60 may be moved in a vertical direction while being mounted on the first rack 40.

In detail, before the cooler 60 contacts the sample tube 70, the cooler catching portion 69 is seated on the cooler hanger 41, thereby restricting downward movement of the cooler 60. As the cooler catching portion 69 is pressed by the elastic member 85, upward movement is limited. Therefore, the cooler 60 may be stably moved while mounted on the first rack 40.

FIG. 5B shows the moment when the cooler 60 contacts the sample tube 70, and FIG. 5C shows that the first rack 40 after the cooler 60 contacts the sample tube 70. It shows the movement further downward.

5B and 5C, according to a user's manipulation, the support part 31 moves downward, and when a predetermined length is moved, the lower end portion of the cooler 60 contacts the upper end portion of the sample tube 70. Since the cooler 60 and the sample tube 70 are arranged side by side with each other, the discharge port 62 may be in contact with the inside of the sample tube inlet 72. In addition, since the lower end of the cooler 60 and the sample tube inlet 72 are formed in a shape corresponding to each other, the periphery of the discharge port 62 is the lower end of the cooler 60 and the sample tube inlet 72. ) Can be sealed by contact.

Therefore, the gas introduced into the cooler 60 or the gas generated in the sample tube 70 may be prevented from flowing out.

When the cooler 60 is in contact with the sample tube 70, the cooler 60 can no longer be moved downward.

In this case, the hook 513 is not fitted into the hook groove 431.

When the support part 31 continues to move downward, the first rack 40 and the cover 80 fixed to the support part 31 move together with the support part 31. As the cover 80 moves, the elastic member 85 is compressed to apply an elastic force to press the cooler catching portion 69 downward.

The cooler 60 is pressed in the direction of the sample tube 70 by the elastic force of the elastic member 85, the contact state can be maintained more closely.

In addition, the support part 31 may be lowered until the hook 513 is fitted into the hook groove 431. Since the displacement of the elastic member 85 increases as the movement amount of the support part 31 increases, the cooler 60 may be in close contact with the sample tube 70 with a stronger force.

In this case, the hook groove 431 is formed to correspond to the size of the hook 513, so that the support 31 is no longer lowered after the hook 513 is caught by the hook groove 431. Can be. Therefore, it is possible to prevent the problem that the cooler 60 is damaged by applying excessive force to the cooler catching portion 69.

When the hook 513 is fitted into the hook groove 431, the second rack 50 may also move together when the first rack 40 is raised. Even in this case, since the deformed state of the elastic member 85 is maintained as it is, the combined state of the cooler 60 and the sample tube 70 can be maintained firmly.

According to the stand 1 for the cooler according to the embodiment of the present invention as described above, there is an advantage that a plurality of the cooler 60 can be used in the experiment at the same time.

In addition, there is an advantage that the condensate generated from the cooler 60 can be collected at the same time through a plurality of the sample tube (70).

In addition, the heating unit 20 is provided, there is an advantage that the sample tube 70 can be used directly for the same purpose as the reaction chamber.

In addition, the moving part 30 is disposed at the rear of the first rack 40 and the second rack 50 on which the cooler 60 and the sample tube 70 are mounted, so that the cooler 60 and By opening the lateral space of the sample tube 70, the cooler and the sample tube of the rear side can also easily observe the experimental state from the side.

In addition, the experiment can be carried out more conveniently by automatically moving the cooler 60 in the vertical direction.

In addition, by providing the cover 80 with the elastic member 85 for forcing the cooler 60 in close contact with the sample tube 70, the cooler 60 of the sample tube 70 The adhesion state can be kept more firm. Therefore, it is possible to prevent the gas to be condensed outflow.

The scope of the present invention is not limited to the above-described embodiments, and the embodiments may be changed, added, or deleted within the scope of the spirit of the present invention.

10 case 20 heating part
30: moving part 40: first rack
50: second rack 60: cooler
70: sample tube 80: cover
85: elastic member

Claims (21)

A first rack on which at least one cooler is placed;
A cover provided on one side of the first rack and provided with an elastic member for pressing the cooler;
A second rack provided in the other direction of the first rack, in which at least one sample tube is placed in selective contact with the cooler; And
A moving unit for moving the first rack in the second rack direction is included,
The sample tube is formed to seal around the condensate outlet of the cooler,
And the elastic member is provided to press the cooler toward the sample tube. The method of claim 1,
The elastic member
And the cooler is provided to be deformed according to the movement of the first rack after the cooler contacts the sample tube. The method of claim 1,
And a heating unit for heating the sample tube. The method of claim 1,
The cooler includes a locking portion mounted to the first rack,
The elastic member is a stand for a cooler, characterized in that for pressing the engaging portion. The method of claim 1,
And the cover is fixed to the first rack and moves with the first rack. The method of claim 5, wherein
The cover includes an elastic member receiving portion for receiving the elastic member,
The catching part for mounting the cooler on the first rack is moved in the elastic member accommodating part. The method of claim 1,
Cooler stand, characterized in that further comprising an operation unit for operating the moving unit. The method of claim 1,
In the moving unit,
A support part fixed to the first rack and reciprocating in one direction;
A guide part for guiding a reciprocating motion of the support part; And
And a driving unit for providing a driving force to move the supporting unit. The method of claim 8,
The guide unit is a cooler stand, characterized in that disposed on the rear side of the first rack and the second rack. The method of claim 1,
And said cooler is a reflux cooler. case;
A support part provided to be reciprocated in the vertical direction and including an arm extending forward of the case;
A guide part for guiding the movement of the support part;
An upper rack detachably coupled to the arm and configured to seat a catch of the cooler;
A cover coupled to an upper side of the upper rack and having an insertion portion into which the cooler is fitted;
An elastic member mounted to the insertion part to press the locking part; And
A lower rack on which a sample tube collecting the condensate formed in the cooler is seated,
The lower rack is arranged to selectively contact the cooler and the sample tube as the support moves.
The stand for the cooler, characterized in that the elastic member is provided to be compressed by the engaging portion in accordance with the movement of the cover. The method of claim 11,
The guide portion is formed inside the case,
The arm is a stand for a cooler, characterized in that exposed to the outside of the case. The method of claim 12,
Further comprising a driving unit for providing a driving force for moving the support,
The guide unit includes a worm gear rotated by a motor included in the drive unit,
The rear side of the support is a cooler stand, characterized in that the rack is interlocked with the worm gear is formed. The method of claim 11,
And the cover is coupled to the upper rack after the cooler is seated in the upper rack. The method of claim 11,
The stand for a cooler, characterized in that it further comprises a heater for heating the sample tube. The method of claim 11,
The elastic member is provided with a compression spring,
The cooler stand, characterized in that inserted into the compression spring inside. The method of claim 11,
Cooling stand is characterized in that the locking portion is moved in the insertion portion. The method of claim 11,
The condenser discharge outlet of the cooler is formed in the contact portion with the sample tube. The method of claim 11,
The elastic member
And the displacement of the upper rack becomes larger as the upper rack approaches the lower rack after the cooler contacts the sample tube. The method of claim 11,
Any one of the upper rack and the lower rack is provided with a hook,
The other stand of the upper rack and the lower rack is a stand for a cooler, characterized in that the hook groove is coupled to the hook is formed. The method of claim 20,
The hook is a stand for a cooler, characterized in that the elastic member is fitted into the hook groove in a deformed state.

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