KR101145116B1 - Apparatus for eliminating frost of freezer - Google Patents

Abstract

PURPOSE: A defrosting device of a quick freezer is provided to improve the defrosting effect by spraying the compressed air to the upper direction through a nozzle in a bottom of a heat exchanger, giving a shock to the dropwise. CONSTITUTION: A defrosting device of a quick freezer comprises a frame, a distribution pipe, a distribution pipe guide unit and a power transmission device. The compressed air offered from a compressor flows into the distribution pipe. A plurality of nozzles is installed in longitudinal direction of the distribution pipe. The distribution pipe guide unit comprises a distribution pipe guide rail and a distribution pipe moving block. The distribution pipe moving block is connected to the distribution pipe guide rail. The distribution pipe moves to front and rear direction of the frame with being installed in the frame by the distribution pipe guide unit. The power transmission device is a cam device for converting the rotational motion into the linear motion.

Description

Apparatus For Eliminating Frost Of Freezer

The present invention relates to a quick freezer for rapidly freezing a product such as food, and more particularly, to a drop freezing apparatus of a quick freezer having a solid durability while more easily performing the removal of a drop. It is about.

Rapid freezing is a device for freezing products such as foods in a short time by using cold air generated through a heat exchanger (evaporator), and a fan motor including a blower fan is installed on the upper side of the heat exchanger to generate a heat exchanger. The cold air is sent to the conveyor side on which the product is mounted and circulated, thereby rapidly freezing the product.

As the moisture contained in the product introduced into the quick freezer evaporates, the frost (frost) accumulates in the lower part of the heat exchanger in combination with cold wind, which reduces the refrigeration efficiency significantly by interrupting the air flow in the heat exchanger and energy. Excessive consumption will have to be removed periodically.

Conventionally, frost generated on the heat exchanger side was removed by using hot water, a heater, and hot gas in addition to water, but it was time consuming and inefficient as well as problems such as high energy consumption and environmental pollution. .

Therefore, a device that physically removes droplets by spraying air from the bottom of the quick freezer has been proposed. However, since the fixed type is adopted, the range of jetting air is limited and impacts on the fins provided in the quick freezer. In many cases, the cooling fins were damaged. On the other hand, a rotating nozzle for changing the injection direction while rotating by the supplied air pressure has been proposed, and an apparatus for reciprocating the injection pipe by its own method has been provided.

Conventionally, a transfer device such as a screw rod is used, but when the water is frozen in the thread, the operation may be stopped. When the structure of the freezer is very long, the installation of the device is complicated and expensive.

An object of the present invention for the above problems, to provide a dropping device is installed on the bottom of the heat exchanger of the quick freezer, in particular to remove physically by using the air pressure, it is a movable structure to prevent the concentration or bias of the air pressure It is possible to supply air pressure to the heat exchanger as uniformly as possible, and a specific object of the present invention is to provide an apparatus for removing a drop with a structure that can be installed at a low cost even in a long heat exchanger.

The above object is, as a device for physically removing the droplets attached to the core of the heat exchanger by injecting compressed air upward in the state installed in the heat exchanger bottom of the quick freezer;

An elongated cuboid-shaped frame in a horizontal direction; A distribution pipe in which compressed air supplied from a compressor is introduced and spaced apart from a plurality of nozzles along a length direction; The distribution pipe guide rail is installed at two or more places on the frame and the first movable block fixed to the bottom of the distribution pipe and coupled to the distribution pipe guide rail, so that the distribution pipe is installed in the frame Distribution pipe guide means for allowing the frame to move forward and backward; A power transmission mechanism for causing the distribution pipe to reciprocate in the front and rear directions of the frame by using a rotational force of a drive motor;

The power transmission mechanism is a cam mechanism for converting a rotational movement into a linear movement, the cam member is rotated about an axis perpendicular to the ground by the drive motor; One end is connected to a point spaced from the center of rotation of the cam member, the other end is achieved by the dropping device of the quick freezer characterized in that it comprises a link means connected to the distribution pipe.

According to a feature of the invention the link means, a center rail which is installed in parallel with the distribution pipe guide rail at the point where the cam member is located; A center link connected to a center block of which one end is connected to the cam member and the other end is moved along the center rail; A pair of first links, one end of which is connected to the center block so as to be symmetrical about the center rail, and the other end of which is fluidly connected to the left and right sides of the distribution pipe along the longitudinal direction of the distribution pipe; A pair of second links, one end of which is connected to the middle of the first link and each other end of which is symmetrical about the center rail, and the other end of which is movably connected along an extension direction of the center rail;

The distribution pipe may be reciprocated in the front and rear directions of the frame by the rotation of the cam member.

According to a feature of the invention, the nozzle,

A head portion capable of rotating using a tool; A nozzle body which is integrally formed on the bottom of the head part 9 and comprises a cylindrical body part in which a plurality of first injection holes are provided along the circumferential direction;

An annular rotary spraying body having a hole in the center of which the nozzle body can be fitted and having a plurality of second spraying holes penetrated in a spiral manner in a circumferential direction; By including the coupling ring body is provided in the ring shape is provided with a limiting jaw for allowing the rotatable spraying body to be freely rotatable even when fitted to the nozzle body; The compressed air may be rotated to be injected while being inclined and rotated about the vertical axis.

According to the above configuration, by spraying the compressed air in the upper direction from the lower portion of the heat exchanger through the nozzle is provided an apparatus for performing the operation to remove the impact on the enemy. Since there is no screw rod or conveyor structure, there is no problem that foreign matter gets caught in small gaps, and thus the failure rate is lowered. In addition, since the distribution pipe itself in which the nozzle is installed is reciprocated under the heat exchanger, compressed air can be uniformly sprayed. As a result, the spraying area of the compressed air can be more widely and evenly distributed, and the effect of eliminating the drop is extremely improved.

1 is a schematic front view of a quick freezer showing an installation state of an apparatus for removing a drop in rapid freezer according to the present invention.
2 is a perspective view of an apparatus for removing a drop in a quick freezer according to an embodiment of the present invention, and FIG. 3 is a plan view.
Figure 4 is a plan view showing step-by-step use state of the dropping device of the quick freezer according to an embodiment of the present invention.
5 is a perspective view of a nozzle according to an embodiment of the present invention, Figure 6 is a longitudinal cross-sectional view.
7 is a plan view of the droplet removal apparatus according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. First, the background will be described with reference to FIG. 1.

The drop elimination device of the quick freezer of the present invention (hereinafter, referred to simply as a dropwise removal device) is installed at the bottom of the heat exchanger 200 of the quick freezer 100. To this end, the heat exchanger 200 is installed in a state spaced apart at a predetermined height in the upward direction from the ground. The heat exchanger 200 is installed inside the freezing compartment 300, and the product to be frozen is continuously introduced into the freezing compartment 300 through a conveyor (not shown) and frozen and discharged.

Hereinafter, the present invention will be mainly described with reference to FIGS. 2 and 3, and the following description will be made with reference to the necessary place. For reference, in the following description, the term "connection" refers to a joint connection that allows relative rotational motion on a specific plane unless a special terminology is attached.

An elongated cuboid-shaped frame 3 is installed in the bottom space of the heat exchanger 200 (see FIG. 1). Hereinafter, the term 'length' of the frame refers to the length in the left and right directions (X-axis direction), and the term 'width' refers to the length of the front-back direction (Y-axis direction).

An elongated distribution pipe 5 corresponding to the length of the frame 3 is installed so as to reciprocate in the front-rear direction (Y-axis direction) of the frame. For this purpose, firstly, a distribution pipe guide means for allowing the distribution pipe 5 to be moved should be provided. The distribution pipe guide means is fixedly installed at the bottom of the distribution pipe (5) and the distribution pipe guide rail (7) installed in two or more places along the left and right directions of the frame (3) and coupled to the distribution pipe guide rail (7). Dispensing pipe moving block 9 is included. The extending direction of the distribution pipe guide rail 7 is the same as the width direction of the frame 3. If the length of the frame 3 is long, the distribution pipe guide rail 7 may be installed at four locations as shown. As the distribution pipe guide means, a known LM guide may be used, and a roller type may be used. The other guide means described below may likewise use an LM guide.

Compressed air supplied from a compressor (not shown) flows into the distribution pipe (5), and a plurality of nozzles (11) are installed in several places along the longitudinal direction of the distribution pipe (5). The nozzle 11 is configured to spray compressed air upwards and details thereof will be described later. The number of nozzles 11 may be arbitrarily selected in consideration of the injection range, the injection pressure, the size of the heat exchanger, and the like.

A drive motor 13, which is a power source for activating the distribution pipe 5, is installed in front of the center of the frame 3. As shown, the output shaft 13a of the drive motor 13 is perpendicular to the ground. The heart of the invention lies in the power transmission mechanism described below. The power transmission mechanism uses the rotational force of the drive motor 13 to cause the distribution tube 5 to reciprocate in the front and rear directions of the frame 3. According to a feature of the present invention, a cam mechanism for converting a rotational motion into a linear motion is used as the power transmission mechanism.

The core of the cam mechanism is the cam member 15. The cam member 15 is rotated about an axis 13a perpendicular to the ground by the drive motor 13 to have a rotating surface parallel to the ground. The cam member 15 may be in the form of a disc or may be in the form of a lever as shown. That is, the shape of the cam member 15 may be variously changed.

The link means is connected between the cam member 15 and the distribution pipe 5. As a result, the rotational motion of the cam member 15 by the driving motor 13 is converted into the linear motion of the distribution pipe 5 through the link means.

The link means may also be variously changed and illustrated is only one example. First, an example of a link means will be described with reference to those shown in FIGS.

The center rail 17 is installed in parallel with the distribution pipe guide rail 7 at the center of the frame 3 where the cam member 15 is located. In the center rail 17, a plurality of through-holes 17a are perforated in the vertical direction along its longitudinal direction, so that frost falling from the top passes through the center rail 17 without falling down.

The center link 19 is connected to the center block 21 where one end is connected to the cam member 15 and the other end is moved along the center rail 17. As a result, when the driving motor 13 starts, the center block 21 performs a reciprocating linear motion along the center rail 17 in the width direction of the frame 3. When the width of the frame 3 is short, as shown in FIG. 7, the distribution pipe 5 may be directly connected to the other end of the center link 19. However, if the length of the frame 3 reaches, for example, 3 to 4 m, link means as shown in Figs. The link means will be described below.

The first link 23 is connected between the center link 19 and the distribution pipe (5). The first link 23 is paired and starts to symmetrically with respect to the center rail 17. The other end of the first link 23 is connected to a position biased to one side of the distribution pipe 5, and according to the geometric analysis, the first link 23 should correspond to the length change according to the cam motion. To this end, a first link block 25 is installed at the other end of the first link 23, and the first link block 25 is fixed to the bottom of the distribution pipe 5 along the extension direction of the distribution pipe rail 27. ).

Meanwhile, the second link 29 is connected between the first link 23 and the center rail 17. The second link 29 is also provided in pairs and is symmetrical with respect to the center rail 17.

One end of each of the second links 29 is connected to the middle of the first link 23 (a point about 1/3 length from the point connected to the center rail 17), and the other end thereof is the center rail 17. Is connected to the rear end of the.

The use state by the above structure is demonstrated with reference to FIG. 4 (a) (b) (c) which is a top view.

The center of rotation of the cam member 15, i.e., the distance L between the output shaft 13a of the drive motor and the connection point between the center link 19, determines the stroke of the cam, and the distance L is the stroke. Corresponds to 1/2 of. When the cam member 15 is rotated by the drive motor 13, the other end of the center link 19 reciprocates linearly in a distance corresponding to the stroke along the center rail 17. 4 (a) shows a state in which the distribution pipe 5 is located on top of the frame 3 in the drawing. When the cam member 15 is rotated 90 ° counterclockwise to come to the position of FIG. 4 (b), the center block 21 moves downward to pull the first link 23 to pull the distribution pipe 5. Move downward in the drawing.

When the cam member 15 rotates 180 ° in this manner, the distribution pipe 5 is placed at the bottom of the frame 3 in the drawing as shown in FIG. In this way, the rotation of the cam member 15 causes the distribution pipe 5 to be converted into a linear reciprocating motion along the width direction of the frame 3. In this process, the compressed air is injected upward from the bottom of the heat exchanger 200 through the nozzle 11.

In this case, although compressed air injected from the nozzle 11 is diffused, a section having a weak injection pressure exists between each nozzle 11. A method for minimizing this part is proposed through the nozzle 11 described next.

Hereinafter, the nozzle 11 according to the embodiment of the present invention will be described with reference to FIGS. 5 to 6. Since the nozzle 11 is described in detail in Korean Patent No. 10-1040513 registered in the Republic of Korea by the present inventor, it will be abbreviated as below.

The nozzle 11 is composed of the nozzle body 53, the rotary spraying body 55, and the detail of the coupling ring body 57, and is rotated about a vertical axis by compressed air pressure.

The nozzle body 53 is composed of a head portion 59 and the body portion 61. The head portion 59 has at least one pair of parallel vertical surfaces F (see FIG. 6) so as to be rotated using a tool such as a wrench. The body portion 61 is formed integrally with the bottom of the head portion 59, and has a cylindrical shape having an outer diameter smaller than the diameter of the head portion 59 so that the annular stopper 63 is formed downward. A first screw thread 65 is provided below the outer circumferential surface of the body portion 61; Between the upper end of the body portion 61 and the first screw thread 65, a plurality of first injection holes 67 passing through the recess section 71 of the cylindrical wall of the body portion 61 is provided along the circumferential direction. A second screw thread 69 for fastening with the distribution pipe 5 is provided below the inner circumferential surface of the body portion 61.

The annular rotary spraying body 55 has a cylindrical side wall 73 and an upper plate 75 having a hole through which the nozzle body 53 can be fitted at the center as being integrally attached to the upper and lower ends of the side wall 73. And a lower plate 77. The upper plate 75 is provided with a plurality of second injection holes 79 formed to penetrate along the circumferential direction. The rotary spraying body 55 is fitted only to the stopping jaw 63 of the head 59 through the lower portion of the nozzle body 53.

The coupling ring 57 is formed in a thread on the inner circumferential surface of the coupling ring 57 so as to be screwed to the first screw thread 65; Restriction jaw 81 for allowing the rotary spraying body 55 to be freely rotatable even in a state where the rotary spraying body 55 is fitted to the nozzle body 53 by limiting a screwing depth with the first screw thread 65 at the lower end of the inner circumferential surface of the coupling ring 57. ) Is prepared.

According to this, the compressed air flowing from the lower end of the nozzle body stays in the pressure storage space S made by the recess section 71 and the rotary spraying body 55 of the body portion 61, and then the second spraying hole 79 Through the inclined to be injected to the outside. In addition, by the law of action reaction, the rotary spraying body 55 is rotated about the vertical axis (V).

1: Dropping device of rapid freezer 3: Frame
5: Distribution pipe 7: Distribution pipe guide rail
9: distribution pipe moving block 11: nozzle
13: drive motor 15: cam member
17: Center Rail 19: Center Link
21: Center Block 23,29: 1st, 2nd Link
25: link block 27: distribution pipe rail
53: nozzle body 55: rotary spraying body
57: coupling ring 59: head
61: body 63: jersey
65,69 first and second thread 67 first injection hole
71; Groove interval 73; Side wall
75; Upper plate 77; Bottom plate
79; 2nd injection hole 81; Limit
100: quick freezer 200; heat transmitter
F; Vertical plane S; Pressure storage

Claims (3)

An apparatus for physically removing a drop in the core of the heat exchanger 200 by spraying compressed air upward while being installed at the bottom of the heat exchanger 200 of the quick freezer 100;
A frame 3 having an elongated rectangular parallelepiped shape in a horizontal direction; A distribution pipe 5 into which compressed air supplied from a compressor is introduced and spaced apart from the plurality of nozzles 11 along a length direction; Distribution pipe guide rails 7 installed at two or more places on the frame 3 and distribution pipe moving blocks 9 fixedly installed at the bottom of the distribution pipe 5 and coupled to the distribution pipe guide rails 7. Distribution pipe guide means for allowing the distribution pipe (5) to move in the front-rear direction of the frame (3) in a state in which the distribution pipe (5) is installed in the frame (3); A power transmission mechanism for causing the distribution pipe 5 to reciprocate in the front and rear directions of the frame 3 by using the rotational force of the drive motor 13;
The power transmission mechanism is a cam mechanism for converting a rotational movement into a linear movement, the cam member 15 is rotated about an axis perpendicular to the ground by the drive motor 13; One end is connected to the point away from the center of rotation of the cam member (15), the other end of the rapid freezing device removal device characterized in that it comprises a link means connected to the distribution pipe (5).
The method of claim 1, wherein the link means,
A center rail 17 installed parallel to the distribution pipe guide rail 7 at a position where the cam member 15 is located; A center link (19) connected at one end to the cam member (15) and at the other end connected to a center block (21) for maneuvering along the center rail (17); Each end is connected to the center block 21 so as to be symmetrical with respect to the center rail 17, and the other end thereof has a lengthwise direction of the distribution pipe 5 at left and right sides of the distribution pipe 5. A pair of first links 23 fluidly connected along the pair; A pair of one end is connected to the middle of the first link 23 and the other end is movably connected along the extension direction of the center rail 17 so as to be symmetrical about the center rail 17. Dropping device of the rapid freezer, characterized in that it comprises a second link (29).
The method of claim 1, wherein the nozzle 11,
A head portion 59 which can be rotated using a tool; A nozzle body (53) formed integrally with the bottom of the head (59) and including a cylindrical body portion (61) in which a plurality of first injection holes (67) are provided in a circumferential direction;
An annular rotating spraying body 55 having a hole in which the nozzle body 53 can be fitted, and having a plurality of second spraying holes 79 formed to penetrate in a spiral manner in a circumferential direction; By including a coupling ring (57) having a limiting jaw (81) is provided in a ring shape for allowing the rotatable spraying body (55) to be rotatable freely even when fitted to the nozzle body (53); Compressed air is injected in the inclined direction and further rotated around the vertical axis (V) dropping device of the rapid freezer, characterized in that the spraying.

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