KR100479022B1 - Perfect airtight-type cage system for protecting transition of pathogen - Google Patents

Abstract

The present invention relates to a cage system for laboratory animal breeding, to be used in a general laboratory unit as well as a clean room so that the experimental animal during the experiment can be more safely protected against various bacteria that may be introduced from the outside. A bucket having a sealing stopper coupled to the opening of the tank, the tank having an opening, a nozzle for allowing water to flow out by suction of an experimental animal, and a through hole into which the nozzle is inserted; Feed container having a plurality of feed discharge slot is formed at a predetermined interval; A housing including a main body having a space necessary for breeding experimental animals therein, and a cage cover formed with a water container accommodation groove and a feed container accommodation port; Receptacle cover for blocking the access of air through the feed container receiving port; Consists of a clamp that is mounted on the front and rear surfaces of the main body to fasten the main body and the cage cover to maintain the coupling state, the airtightness is further increased, the stress that can be received by the experimental animals are reduced, the cage system It provides a cage system for laboratory animal breeding, which makes the management work easier and more convenient.

Description

PERFECT AIRTIGHT-TYPE CAGE SYSTEM FOR PROTECTING TRANSITION OF PATHOGEN}

The present invention relates to a cage system for experimental animal breeding, and more particularly, to experiment with an air conditioner including an air supply means and an air discharge means that can be used in a general laboratory that is not equipped with a clean room as well as a clean room. It relates to a cage system for breeding experimental animals mounted on the animal breeding rack system in a sealed state with external air so that the experimental animals in the experiment can be raised in a safe state against various germs that may be introduced from the outside.

In general, when developing a new drug, clinical trials must be conducted to confirm the efficacy and toxicity of the drug. In this case, animal experiments are carried out to confirm the side effects of the drug to be tested in advance before conducting a clinical experiment on a high risk person, and mice having excellent breeding power are mainly used for such animal experiments.

Experimental animals such as mice, which are used for clinical trials, are often raised in clean rooms with large facilities, but they are reliable in various experiments when animal experiments are carried out in lab units of universities or small and medium-sized enterprises that do not have clean rooms. You need to secure it. In other words, during the long-term carcinogenic or toxicological experiments, it is possible to prevent the death of experimental animals due to external infections, and to separate various types of laboratory animals in the same space as in the case of breeding sterile and infected animals at the same time. In case of breeding, mutual infection is prevented, and it is also necessary to prevent the infection of the manager who manages the experimental animal by the experimental animal.

Hereinafter, an example of a cage system for laboratory animal breeding according to the related art used for the above uses will be described with reference to the accompanying drawings.

1 is a schematic perspective view showing a general laboratory animal breeding rack system, Figure 2 is a perspective view showing an example of a cage system according to the prior art, Figure 3 is an exploded perspective view of FIG. Figure 4 is a front view of the cage system shown in Figure 2, Figure 5 is a side view of the cage system shown in Figure 2, Figure 6 is a cross-sectional view showing the receiving structure of the bucket according to the prior art, Figure 7 is Figure 2 It is sectional drawing which shows the feed container accommodation structure of the cage system shown in FIG.

In the cage system for experiment animal breeding, for example, about 6 to 6 experiment animals such as mice are bred, and as shown in FIG. 1, it is used in combination with a rack system for accommodating a plurality of cage systems, or in a rack system. It can be used independently without being combined.

The rack system 10 includes an air supply means 11 for sucking fresh air from the outside to filter the contaminants and supplying it to the cage system 1 and an air discharge means for discharging the supplied air again. An air conditioner is provided.

The air supply means is provided with an air supply nozzle for supplying fresh air coupled to the cage system, and the air discharge means is also provided with an air discharge nozzle for discharging contaminated air inside the cage system by being coupled to the cage system. have.

Therefore, the cage system 1 for experimental animals is mounted in the rack system 10 to receive sterile fresh air in a forced air circulation system, and discharges contaminated air inside the cage system to the outside.

2 and 3, the cage system for experimental animal breeding according to the prior art is formed of a polycarbonate material, a box having a rectangular cylindrical shape that provides a space for breeding experimental animals, and the box (2) Is coupled to the top of the overall forming the sealed housing 20, the front end nozzles of the feed container (4) and the water container (5) from the outside to the receiving groove (21) formed on one side to seal the coupling into the interior of the housing (20) It includes a cage cover (3).

The rectangular box is provided with an air inlet and an air exhaust port respectively coupled to the air supply nozzle and the air exhaust nozzle of the rack system when mounted to the rack system, and the cage cover 3 is provided in the receiving groove 21. When the cage system 1 is independently used on the other side, an air vent 8 is formed which seals the air inlet 6 and the air exhaust 7 and can supply the filtered air to the inside.

The detailed structure of the cage system will be described in more detail. As shown in FIGS. 4 and 5, the cage cover 3 is hermetically coupled to the square box 2 at both sides of the cage cover 3. A pair of locking devices 22a and 22b are attached to prevent the cage cover 3 from being easily separated, and the groove formed at the lower end of the outer circumference of the cage cover 3 is formed so that the upper end of the square box 2 is sealed to the groove. -Ring 23 is inserted.

One end of the locking device (22a, 22b) is hinged to the cage cover (3), the fixing members (22c, 22d) protruding inward from the handle is fixed to the fixing jaw (2a, 2b) of the rectangular box (2) Each has a structure that is snapped together.

The air inlet 6 and the air outlet 7 have a sealing structure similar to each other, the first bracket 93 having the through hole 93a formed in the groove formed in the center and the second bracket having the through hole in the center ( 96 is press-bonded to the through-hole of the rectangular box (2) from the inside / outside to form a structure fixed to the square box (2) while maintaining the outer peripheral portion sealing state.

The movable member 97 having a plurality of air inlet holes 95 formed at the center thereof is elastically inserted into the through hole 93a by an elastic spring 94 to the groove of the first bracket 93. Is placed. Then, the inlet hole 95 provided in the movable member 97 is sealed and the stem 91b protruding outward from the center extends to the outside through the central through hole 95a of the movable member 97 and then bushes. It is fixed to the coupling nut 98 through, and the sealing plate 91 having a plurality of holes (91a) is coupled along its outer periphery.

Therefore, when the cage system 1 is not normally coupled to the rack system 10, the sealing plate 91 is in close contact with the movable member 97 by the elasticity of the elastic spring 94 to be cut off from the outside. A sealing state is achieved.

However, when the cage system 1 is coupled to the rack system 10, the elastic spring 94 is compressed by the pressure of the air supply nozzle 14 and the air discharge nozzle 15 and the movable member 97 is removed. When the one is in close contact with the groove of the bracket 93, the sealing plate 91 also retreats to the inside of the rectangular box 2 to release the sealing state, and the plurality of air inlet holes 95 formed in the movable member 97 are closed. Each of the air supply nozzle 14 and the air discharge nozzle 15 communicates with the inside of the cage system 1 to supply air, and the air therein is discharged to the outside.

On the other hand, the bucket provided in the cage system for experimental animal breeding according to the prior art, as shown in Figure 6, made of a transparent or semi-transparent polycarbonate material, a square marked with a scale for displaying the residual amount of water on the surface A sealing member 52 formed with a cylinder 51, an insertion hole 52a which is forcibly fitted to the insertion hole 51a of the square cylinder 51 and penetrated to the inner center, and an insertion hole 52a of the sealing member. It is forcibly fitted to a) and consists of a bucket nozzle (53) in which the water contained in the rectangular cylinder (51) can be discharged by suction.

In addition, the bucket nozzle 53 is detachably coupled to the bucket mounting sealing coupling device 50 formed in the receiving groove 21 of the cage cover 3 in a sealing state.

On the other hand, the feed container for feeding the experimental animal, as shown in Figure 7, the cylindrical case 61 made of a transparent polycarbonate material and the upper and lower openings for feeding the feed, and the cylindrical case 61 Opening and closing the upper part of the opening and closing cap 63 and a plurality of feed discharge configured to maintain the sealed state to prevent the contamination of the mouse or feed from the pollutant source is completely blocked inside and the inside of the cylindrical case 61 when combined It is made of a stainless steel so as to have a hole (62a) comprises a feed nozzle nozzle 62 is coupled to the lower portion of the cylindrical case (61).

In addition, the feed container nozzle 62 is detachably coupled to the feed container mounting sealing coupling device 60 formed in the receiving groove 21 of the cage cover 3 in a sealing state.

However, the cage system according to the prior art as described above has a number of problems that can be adverse to the breeding environment of the experimental animal, and also has a number of problems that make the management of the cage system difficult.

For example, while raising a laboratory animal while the cage system is mounted in a rack system, a rubber-like guide bushing must be maintained, except that air flow through the rack system air supply and air exhaust nozzles must be maintained. In addition, there is a problem in that the airtightness of the feed container mounting sealing coupling device mounted on the cage cover for the coupling of the feed container is composed of a bracket of the strainless material for fixing the same, and also includes a feed container nozzle and a cylindrical case. When the feed container is removed from the cage cover for feed supplement or washing, there is a problem that the feed container nozzle and the cylindrical case is separated from each other, accompanied by inconvenience.

In addition, in the case of a water tank for supplying water to the test animals, a bucket nozzle for allowing water to flow out by suction is mounted perpendicularly to the sealing coupling means for mounting the water tank of the cage cover, so that the test animal to be bred has moisture. There was a problem in that the neck had to be ingested for ingestion, thus causing the animals to be stressed and the influence to the experimental data.

On the other hand, the cage system according to the prior art, the O-ring (23) is made to seal the upper end of the square box (2) in the groove formed in the lower periphery of the cage cover for the airtight between the rectangular box and the cage cover It was inserted. However, when the autoclave operation of the cage system for sterilization washing, the O-ring is deformed by heat as it is exposed to high temperature and high pressure, thereby easily coming out of the groove. In addition, components including a rectangular box and a cage cover formed of a polycarbonate material also have a problem that deformation due to heat may occur due to exposure to high temperature and high pressure during autoclave operation.

In addition, as the locking device provided for coupling the rectangular box and the cage cover is installed on the cage cover side, the locking device is released when the cage cover is released and the cage cover is lifted for cleaning the cage system. There was a problem that the member is caught by the upper edge of the rectangular box, making it difficult to separate, and also the locking device can be fastened even when the cage cover is not correctly placed in place on the rectangular box, accompanied by careful attention from the manager If not, there was a problem that the experimental animal can be exposed to a state that is not confidential.

In addition, in the case of the air inlet and the air outlet, the movable member and the sealing plate come into contact with each other to prevent air from entering and coming into contact with each other without being coupled with the air supply nozzle and the air discharge nozzle, but both the movable member and the sealing plate are stainless. As it is formed of a metal material such as the situation is difficult to maintain mutual confidentiality.

Invented to solve the problems of the prior art as described above,

An object of the present invention is used in a general laboratory unit as well as a clean room, to provide a cage system for raising the airtightness to increase the airtightness to more securely protect the experimental animal in the experiment against a variety of bacteria that can be introduced from the outside It is.

In addition, an object of the present invention is to provide a cage system for experimental animal breeding that can reduce the stress that the experimental animal can be raised.

In addition, the present invention is to provide a cage system for experiment animal breeding to more easily and simply manage the cage system for experiment animal breeding.

The present invention for realizing this,

A bucket including a tank having an opening, a nozzle for allowing water to flow out by suction of a laboratory animal, and a through hole into which the nozzle is inserted, and a sealing stopper coupled to the opening of the tank;

Feed container having a plurality of feed discharge slot is formed at a predetermined interval;

A housing including a main body having a space necessary for breeding experimental animals therein, and a cage cover formed with a water container accommodation groove and a feed container accommodation port;

Receptacle cover for blocking the access of air through the feed container receiving port;

It provides a fully sealed cage system for preventing pathogen transfer, including a clamp mounted on the front and rear surfaces of the main body to fasten the main body and the cage cover to maintain a coupled state.

The feed container receiver is characterized in that it has a flange protruding upward to engage the container cover along its boundary.

In addition, the feed container is provided with a fixing flange extending from its upper edge, the feed container receiving port is characterized in that it has a mounting flange for the fixing flange to be caught in its inner peripheral portion.

On the other hand, the tank is formed with an inclined surface in which the surface on which the opening is formed is determined in a predetermined angle range, the bucket receiving groove has an inclined surface formed at an angle corresponding to the inclined surface formed in the tank and the bucket on the inclined surface It characterized in that it comprises a sealing coupling means is mounted so that the nozzle of the sealing coupling.

In addition, the predetermined angle range is preferably 30 ° to 50 °.

Each of the clamps includes a handle member having a top end hinged to the main body, and a fastening member having a bottom end hinged to a central portion of the handle member and a fastening groove provided at a top end contacting the outer circumference of the cage cover when fastened to the cage cover. The cage cover may include a fastening protrusion accommodated in the fastening groove on the front and rear outer circumference edges thereof.

In order to ensure a tight coupling between the main body and the cage cover, a packing member having a plurality of coupling protrusions protruding to a bottom surface is further provided, and an upper end edge of the main body is formed with a recess in which the packing member is mounted. It is characterized in that a plurality of coupling holes are formed in a position corresponding to the coupling protrusion.

The main body is further provided with an air supply port for supplying air to the inside of the housing, the air outlet for discharging the internal air to the outside;

The air inlet and the air exhaust port are respectively coupled to the through hole formed in the rear surface of the main body and the first through-hole is formed in the groove formed in the center and the first bracket and the plurality of air inlet holes formed around the first through hole and And a second bracket having a second through hole in the center and being coupled to the through-hole of the main body with the first bracket inward / outward so that the outer circumferential part is fixed to maintain the sealing state, and the outer side of the groove of the first bracket. A movable member having an outer circumferential portion elastically supported by a spring and communicating with the first through hole at a central portion thereof, and a movable member having a plurality of air inlet holes around the third through hole; And a sealing plate in close contact with the inner surface of the recess of the first bracket to seal the air inlet hole of the first bracket, and a sealing ring attached to the close contact surface of the sealing plate. do.

The air inlet is mounted on the inside of the first bracket of its own, it is preferable to further include a protective cap to prevent noise caused by the contact of the experimental animal, and to prevent the penetration of this material such as a rug into the air inlet. .

Preferably, the air exhaust port further includes a cage exhaust filter mounted inside the first bracket and including a low density filter that primarily filters contaminants having a large particle size.

BEST MODE Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

As shown in Figure 1, the experimental animal breeding cage system (1) according to the present invention, for example, each of the experimental animals, such as a mouse breeding 5 to 6, each rack system to accommodate a plurality of cage systems It is used in combination with (10). Of course, it is also possible to be used separately without being coupled to the rack system 10. That is, when the cage system 1 of the present invention is mounted in the rack system 10 and used in the forced air circulation method, the fresh air in aseptic state is supplied through the air supply nozzle 14 through the air supply means 11. And, the contaminated air inside the cage system is forcibly sucked from the air discharge nozzle 15 through the air discharge means 18 and discharged to the outside. However, as described below, the cage cover filter 109 may be used independently of the rack system 10 without being mounted on the rack system 10.

8 is a perspective view of a cage system for laboratory animal breeding according to the present invention, and FIG. 9 is an exploded perspective view of the cage system shown in FIG. 8. 10 is a cross-sectional view of the cage cover showing the mounting state of the bucket according to the present invention, Figure 11 is a cross-sectional view taken along the line A-A of Figure 9, Figure 12 is a perspective view showing a clamp according to the present invention. FIG. 13 is an enlarged cross-sectional view of portion B of FIG. 10, FIG. 14 is a cross-sectional view of an air inlet according to the present invention, and FIG. 15 is a view showing a protective cap according to the present invention, FIG. 15A is a front view, and FIG. 15B is a side view. 16 is an exploded perspective view of a cage exhaust filter according to the present invention. Finally, Figure 17 is a view showing a rotating plate constituting the cage cover filter according to the present invention, Figure 17a is a plan view, Figure 17b is a cross-sectional view taken along the line A-A of Figure 17a.

The cage system 100 according to the present invention, as shown in Figs. 8 and 9, the cage cover which is coupled to the upper body of the rectangular cylindrical shape 102 and the main body 102 to form an enclosed space as a whole. The housing 104 forms a housing, and a bucket 110 and a feed container 120 for supplying water and feed to an experimental animal are mounted to the cage cover 104 in a detachable structure, and connected to a rack system to supply air. The air inlet 130 and the air exhaust 140 for discharging the internal air is mounted on the back of the main body.

In addition, a pair of positioning guides 103a and 103b for fixing a position in the rack system are formed on both sides of the main body 102, and a pair of positioning brackets (not shown) provided in the frame of the rack system are provided. Snaps into the rack system to secure the position of the cage system (1).

The cage cover 104 is provided with a bucket receiving groove 105 for mounting the bucket 120 on one side of the front part, and has a feed container receiving hole 107 for mounting the feed container 130 on the other side of the front part. When the cage system 1 is independently used at the rear part, the cage cover allows the air to be filtered and the inside air to be filtered out through the air inlet 140 and the air exhaust port 150 even in a closed state. The filter 109 is formed.

In addition, the feed container container 107 is formed on the cage cover 104 in the shape of a square, and is provided with a container cover 108 of a corresponding type to block the entrance and exit of air through it.

Feed container container 107 of the cage cover 104 is provided with a flange 111 protruding upward along its boundary in order to engage the container cover 108 is engaged, as described in detail below Mounting flanges 112 and 113 are respectively provided to extend from the bottom of the inner circumference of the front and rear to mount the feed container 130.

The feed container 130 is manufactured by using stainless, and as shown in Figure 9, the upper and lower left and right plates (131, 132) of the narrowing form as it descends to the bottom and the shape of the side plates (131, 132) It consists of a plurality of longitudinal wires 133 bent in the same shape, a plurality of transverse wires 134 for fixing the wires 133 at equal intervals, and fixing flanges 135 and 136 extending forward and rearward from the top. That is, the plurality of longitudinal wires 133 forms a plurality of feed discharge slots 137 at intervals such that feeds supplied in the form of particles do not fall easily. In other words, the feed discharge slot 137 is formed at intervals slightly smaller than the size of the feed, which is generally provided for breeding the experimental animal, so that the experimental animal intentionally removes the feed from the feed bin for the intake of the feed. If not, the feed is formed at intervals that do not naturally discharge. Therefore, the experimental animal accommodated in the cage system 100 can bite the feed particles partially extruded into the feed discharge slot 137, so that if the size of the feed particles is smaller than the gap of the feed discharge slot, they fall into the cage system. To allow the animals to eat.

The feed container 130 is mounted so that its fixing flanges 135 and 136 are fastened to the mounting flanges 112 and 113 formed in the front and rear sides of the feed container container 107, and the feed container container 107 is the container cover. It is completely sealed by covering 108 with its flange 111.

Meanwhile, as illustrated in FIG. 10, the bucket 120 includes a tank 123 having an opening 121, a nozzle 125 allowing water to flow out by suction of a laboratory animal, and a nozzle. It has a through hole 126 is inserted 125 is composed of a sealing stopper 127 is coupled to the opening of the tank. Here, the surface on which the opening 121 of the tank 123 is formed is formed as an inclined surface having an inclination of about 30 degrees to about 50 degrees, preferably an inclination of about 40 degrees based on the upper surface which becomes a horizontal surface.

In addition, as shown in FIG. 9, the bucket receiving groove 105 of the cage cover 104 faces an inclined surface provided with the opening 121 of the tank 123 when the bucket 120 is mounted. The surface is formed with an inclined surface of a corresponding angle, and the sealing coupling means 129 is mounted to the inclined surface so that the nozzle 125 of the bucket 120 is sealed.

Therefore, the through hole 126 of the sealing stopper 127 coupled to the opening 121 formed on the inclined surface of the tank 123 also has an inclination, and the nozzle 125 inserted into the through hole 126 is also inclined. It has an inclination, the sealing coupling means 129 of the inclined surface of the bucket receiving groove 105, the nozzle 125 is mounted also has a corresponding inclination, when mounting the bucket 120 in the bucket receiving groove 105 The nozzle 125 is placed inside the housing with an inclination. Therefore, the experimental animals raised in the cage system 100 need only lift the head a little to ingest water, thereby minimizing the stress that the experimental animals can receive in the process of eating water. In addition, since the tank 123 containing water is in communication with the bucket nozzle 53 by a sealing stopper 127 made of silicon, airtightness is maintained between the tank 123 and the sealing stopper 127, Therefore, when the experimental animal does not eat water, water may be prevented from leaking through the bucket nozzle 125.

In addition, the cage cover 104 is made of stainless steel integrally coupled to the lower outer surface of the water container receiving groove 105 to prevent the lower portion of the water tank receiving groove 105 is accommodated by the experimental animal. The protector 115 is provided.

On the other hand, as shown in Figure 9 and 11, for the airtight coupling between the main body 102 and the cage cover 104, the groove 141 is formed on the upper edge of the main body 104 In this recess 141, a packing member 145 for airtightness is mounted. The packing member 145 includes a plurality of coupling protrusions 147 protruding to the bottom surface, and a plurality of coupling holes 143 formed in the groove portion 141 at positions corresponding to the coupling protrusions 147. ) Is provided. In more detail, the coupling protrusion 147 of the packing member 145 has a narrow neck portion and a large head portion, and the corresponding coupling hole 143 is the head of the coupling protrusion 147. It is smaller than the part and larger than the neck. Therefore, the packing member 145 is not mounted only by being inserted into the recess 141, but the plurality of coupling protrusions 147 provided therein correspond to the plurality of coupling holes 143 formed in the recess 141. It is coupled to, but is coupled to the head portion of the coupling protrusion 147 to completely exit to the opposite side of the coupling hole 143 of the groove 141 is mounted in a structure that is difficult to pull out artificially.

Then, in order to fasten the main body 102 and the cage cover 104 to maintain a coupled state, a pair of clamps 160 mounted on the front and rear surfaces of the main body are mounted.

As shown in FIGS. 9 and 12, the clamp 160 has a handle member 161 hinged to an upper end of the main body 102, and a lower end hinged to a central portion of the handle member 161. When fastening to the cage cover 104 is composed of a fastening member 165 having a fastening groove 163 in the upper end in contact with the outer rim of the cage cover (104). And, as shown in Figure 13, the cage cover 104, the outer periphery is provided with a fastening protrusion 167 accommodated in the fastening groove 163, the body 102 and the cage cover 104 is further Make sure you are in a reliable fastening state. In addition, the clamp 160 configured as described above is impossible to fasten the clamp 160 in a state in which the fastening protrusion 167 of the cage cover 104 is not correctly inserted into the fastening groove 163. In this case, the clamp 160 is fastened in a state in which the cage cover 104 is not correctly mounted on the main body 102, thereby preventing the possibility that the experimental animal may be exposed to a state in which airtightness is not guaranteed. In addition, since the fastening protrusion 167 is formed not only on the front and rear ends of the cage cover 104, which is fastened to the fastening groove 163 of the clamp 160, but also on the entire outer circumferential portion of the cage cover 104. Along with the anti-bending reinforcement 195 to be described later serves to prevent the deformation of the cage cover 104.

In addition, as illustrated in FIGS. 8 and 9, a plurality of anti-bending reinforcing bars 195 are provided on the upper portion of the outer circumference of the cage cover 104. By providing the anti-bending reinforcement 160, it becomes an advantageous structure to prevent deformation such as distortion of the cage cover 104 even at high temperature and high pressure during the high temperature steam sterilization operation for sterilization and cleaning of the cage system 100.

The air inlet 140 and the air exhaust port 150 have a similar sealing structure, and as shown in FIG. 14, a first through hole 151a is formed in a recess formed in a central portion, respectively, as shown in FIG. The first bracket 151 having a plurality of air inlet holes 151b formed around the through hole 151a, and the second bracket 153 having the second through hole 153a at the center of the main body 102 are provided. The inner circumferential portion is fixed to the main body 102 so as to be crimped together in the inner / outer side with the through-holes formed in the rear surface.

The outer circumferential portion is elastically supported by the spring 155 on the outer side of the recess of the first bracket 151, and the third through hole 157a and the third through hole communicating with the first through hole 151a at the central portion thereof. A movable member 157 having a plurality of air inlet holes 157b is mounted around the 157a and interlocked with the movable member 157 to seal or seal the air inlet hole 157b of the first bracket 151. It is provided with a sealing plate 158 in close contact with the inner surface of the recess portion of the first bracket 151 to open. The sealing plate 158 has a stem 158a protruding to the outside through the third through hole 157a at the center thereof, and an end of the stem 158a is fastened by a nut 158b to be movable. It is coupled with the member 157 to interlock. In addition, by providing a sealing ring 159 attached to the contact surface of the sealing plate 158, that is, the surface in contact with the first bracket 151 to further improve the airtight, the cage system 100 in the rack system It completely blocks the inflow and leakage of air through the air inlet 140 and the air exhaust port 150 in the separated state.

The sealing plate 158 of the air inlet 140 into which outside air is introduced, unlike the case of the air exhaust port 150, has an extended outer peripheral portion, and the expanded outer peripheral portion 158c has a plurality of holes. 158d is formed so that the inflow velocity of the air flowing from the air supply nozzle becomes smooth and is evenly sprayed inside the housing. Accordingly, it is possible to reduce the cause of stress that can be directly received by the experimental animal in the housing.

As described above, the air inlet 140 and the air exhaust port 150 are mounted at mutually diagonal positions on the rear surface of the main body 102, and in detail, the air inlet 140 is mounted at the lower side of one side of the rear surface, The air exhaust port 150 is mounted on the other side of the rear surface. When the cage system 100 is coupled to the rack system, the spring 155 is compressed by the pressure of the air supply nozzle and the air discharge nozzle mounted at the corresponding positions, respectively, and the movable member 157 is the first bracket 151. At the same time, the sealing plate 158 is also retracted to the inside of the main body 102 so that the sealing state is released. As a result, a plurality of air inlet holes 157b formed in each movable member 157 and a plurality of air inlet holes 151b formed in each of the first brackets 151 communicate with the air supply nozzles and the air discharge nozzles, respectively. Air is supplied and exhausted.

The air inlet 140 has a positional property that can be directly in contact with the animal being raised as it is located in the lower rear of the main body, and thus to prevent the noise that may be caused by the contact of the animal, In order to prevent the rugs laid on the bottom of the main body in order to provide a sanitary environment to interfere with the flow of air introduced into the air inlet, as shown in Figure 15, the protective cap 170 inside the air inlet 140 It is additionally equipped. The protective cap 170 is formed with a coupling groove 171 to be coupled by rotating after insertion into the outer peripheral portion, the fastening protrusion (210) is coupled to the coupling groove in the first bracket 151 of the air inlet 140 Not shown). In addition, a plurality of vent holes 173 are formed on the front surface of the protective cap 170 for smooth flow of air.

In addition, as shown in the air inlet 140, the air exhaust port 150, as shown in FIG. 16, a cage exhaust filter 180 for filtering contaminants having a large particle size is provided inside the air exhaust port 150. In addition, a fixing protrusion (not shown) for coupling the cage exhaust filter 180 is formed on the first bracket 151 of the air exhaust port 150. The cage exhaust filter 180 is detachably coupled to the first bracket 151 of the air exhaust port 150. A plurality of vent holes 181 are formed on a front surface thereof, and a coupling groove 182 is provided at an outer circumference thereof. A vent cover 183, a low density filter 185 for filtering contaminants having a large particle size, the filter 185 is accommodated and coupled with the coupling groove 182 provided in the vent cover 183 Coupling protrusion 186 is formed in the outer peripheral portion of the front end and the fixing groove (187) coupled to the fixing projections (not shown) of the first bracket 151 is composed of the filter receptor 188 is formed in the outer peripheral portion.

As described above, as the air exhaust unit 140 includes the cage exhaust filter 180, dust and dust generated from the ingot are generally laid so as to provide comfort to the experimental animals bred and minimize stress caused by excretion. Large contaminants, such as hairs falling from the animal being reared, can be primarily filtered by the low density filter 185 constituting the cage exhaust filter 180, so that the contaminants as described above are discharged and racked. It is possible to prevent the air exhaust nozzle of the system or to continue to accumulate in the pipe communicating with the air exhaust nozzle.

Preferably, the distance between the air inlet 140 and the air exhaust port 150 is set diagonally to be as far as possible. Therefore, the fresh air injected from the air inlet 140 circulates evenly in the cage system 100. After being exhausted to the outside through the air vent 150, the experimental animal breeding in the cage system can suck the air evenly.

On the other hand, because the cage system 100 for laboratory animal breeding according to the present invention includes a cage cover filter 109 on one side of the cage cover 104, for example, a cage in which a laboratory animal is being reared. When transporting the system 100 or when the cage system 100 is used independently without being mounted to the rack system, it is used to supply fresh air filtered with contaminants into the cage system 100, and inside the cage system. Is used to discharge contaminated air to the outside in a filtered state.

The cage cover filter 109 is mounted on the cylindrical flange 193 extending up and down on the cage cover 104, as shown in Figure 9, open in use and maintain a completely closed state when not in use Opening cap 190 for sealing the cylindrical flange (193) at the top to give, a filter (196) for filtering contaminants, the cylindrical flange to block the access of experimental animals and put the filter (196) Aeration fixing plate 198 having a plurality of ventilation holes mounted on the lower portion of 193, and the filter 196 is pressed and fixed on the ventilation fixing plate 198 to prevent its flow and to filter air through the edges. It consists of a rotating plate 199, as shown in FIG. 17, to prevent entry and exit without. Three mounting grooves 194 are formed on the inner circumferential surface of the cylindrical flange 193 in a recessed shape to fix the rotating plate 199, and extend toward the center from the lower end of the cylindrical flange 193. It has a circumferential rim 191 formed on the inner side where the edge of the filter is located. The rotating plate 199 is provided with three mounting protrusions 200 protruding at equal intervals from the outer periphery thereof for coupling to the mounting groove 194, and also through the edge of the filter 196 which is located at the bottom thereof. In order to prevent air from entering without filtration, a contact rim 201 is formed to protrude downwardly along the outer circumference of the bottom surface so as to be in close contact with the circumferential rim 191 formed therein and the filter in between. A handling handle 202 is provided to facilitate the detachment of the rotating plate 199.

The cage system 100 of the present invention is a tank 123 constituting the body 102, the cage cover 104 and the water tank 120 in order to prevent the deformation occurs during autoclave autoclave ) Is preferably made of polysulfone. In general, it can be prepared using a material such as polycarbonate (polycabonate), but the high-pressure steam sterilization operation is carried out at a high temperature and high pressure of about 120 ℃, to be made of polycarbonate (polycabonate) that is thermally deformed at 135 ℃ In case of high pressure steam sterilization, there is a problem that deformation may occur, and it starts to deform at about 174 ° C. In addition, it is preferable to manufacture using polysulfone having superior durability and chemical resistance than the polycarbonate. As well as the polysulfone, it may be prepared using polyetherimide having excellent heat resistance, strength, durability and chemical resistance.

Experimental animal breeding cage system according to the present invention as described above can be used mainly for the purpose of breeding the mouse among the experimental animals, the experimental animal breeding cage system according to the present invention increases its size according to the size of the animal to be breeding It can be applied to breeding of other animals such as rats and rabbits by feeding on them.

On the other hand, the front cover of the cage cover 104 is attached to the label hanger for recording the data, such as the name of the animal to be bred in the cage system 100, the experimental system, the operator in which cage system the animal in the experimental state It is easy to grasp the material, etc., and when the cage system is separated from the rack system and the work is performed again, the cage system is not necessarily coupled to the position where the cage system was first detached. Make it easy to keep track of animal data.

Experimental animal breeding cage system according to the present invention as described above can be removed from the outside of the cage and the feed container and the bucket system, the inside and the outside of the cage system is mounted in a completely sealed state and the feed and without the cage cover The operation of water supply can be made very simple, and it can prevent the polluted air from leaking to the outside during feeding and water supply, and at the same time, the external pollutant flows into the cage system. It has a more reliable sealing structure to prevent it from being retained, which further improves hermeticity.

Therefore, not only the clean room but also the general laboratory unit can prevent the experimental animals from being killed by infection, improve the productivity by simplifying the structure of the cage system, and there is no risk of infection to the cage system. Can be freely moved.

In addition, by reducing the source of stress that can be received by the experimental animals in the source, it is possible to obtain more reliable experimental results data from the experimental animals under test.

In addition, the cage system is prevented from being deformed during the high temperature steam sterilization operation performed for disinfection of the cage system, and the handling of the operator is simplified, and thus the management becomes simpler.

Although the present invention as described above has been shown and described with respect to specific embodiments, various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the appended claims. Anyone who owns it can easily find out.

1 is a schematic perspective view of a rack system for breeding a general experimental animal;

2 is a perspective view showing an example of a cage system according to the prior art,

3 is an exploded perspective view of FIG. 2;

4 is a front view of the cage system shown in FIG.

5 is a side view of the cage system shown in FIG.

6 is a cross-sectional view showing a bucket receiving structure of the cage system shown in FIG.

7 is a cross-sectional view showing a feed container accommodation structure of the cage system shown in FIG.

8 is a perspective view of a cage system according to the present invention;

9 is an exploded perspective view of the cage system shown in FIG. 8;

10 is a cross-sectional view of the cage cover showing the mounting state of the bucket according to the present invention;

11 is a cross-sectional view taken along the line A-A of FIG.

12 is a perspective view of a clamp according to the present invention;

FIG. 13 is an enlarged cross-sectional view of portion B of FIG. 10;

14 is a cross-sectional view of the air inlet in accordance with the present invention,

15 is a view showing a protective cap according to the present invention,

15A is a front view,

15B is a side view,

16 is an exploded perspective view of the cage exhaust filter in accordance with the present invention.

17 is a view showing a rotating plate constituting the cage cover filter according to the present invention,

17A is a plan view,

17B is a cross-sectional view taken along the line A-A of FIG. 17A.

* Description of the symbols for the main parts of the drawings *

100: cage system 102: main body

104: cage cover 105: bucket receiving groove

107: feed container container 108: container cover

109: ventilator 111: flange

112, 113: mounting flange 115: protector

120: bucket 123: tank

125: nozzle 127: sealing stopper

129: sealing coupling means 130: feed container

131 and 132: left and right plates 133: longitudinal wire

134: transverse wire 135, 136: fixing flange

140: air inlet 145: packing member

150: air cutting mechanism 151: first bracket

153: second bracket 155: spring

157: movable member 158: sealing plate

159: sealing ring 160: clamp

161: handle member 163: fastening groove

165: fastening member 167: fastening protrusions

170: protective cap 180: cage exhaust filter

190: opening and closing cap 193: cylindrical flange

195: flexural reinforcement 196: filter

198: fixing plate for ventilation 199: rotating plate

Claims (14)

A bucket including a tank having an opening, a nozzle for allowing water to flow out by suction of a laboratory animal, and a through hole into which the nozzle is inserted, and a sealing stopper coupled to the opening of the tank; Feed container having a plurality of feed discharge slot is formed at a predetermined interval; A housing including a main body having a space necessary for breeding experimental animals therein, and a cage cover formed with a water container accommodation groove and a feed container accommodation port; Receptacle cover for blocking the access of air through the feed container receiving port; It includes a clamp mounted on the front and rear surfaces of the main body to fasten the main body and the cage cover to maintain the coupling state, The feed bin has a fixing flange extending from its upper edge, The feed container receiving port is a completely closed cage system, characterized in that it has a mounting flange for holding the fixing flange to the inner circumference. The method of claim 1, And said feed container receiver has a flange projecting upwardly to engage said container cover along its boundary. delete The method of claim 1; The tank is formed of an inclined surface in which the surface on which the opening is formed is determined in a predetermined angle range, The bucket receiving groove is provided with an inclined surface formed at an angle corresponding to the inclined surface formed in the tank, the hermetically closed cage system having a sealing coupling means for mounting the nozzle of the bucket on the inclined surface. The method of claim 4, wherein The predetermined angle range is 30 ° to 50 ° completely closed cage system. The method according to claim 1 or 5, Each of the clamps includes a handle member having a top end hinged to the main body, and a fastening member having a bottom end hinged to a central portion of the handle member and a fastening groove provided at a top end contacting the outer circumference of the cage cover when fastened to the cage cover. , The cage cover is a completely closed cage system having a fastening protrusion accommodated in the fastening groove on the outer circumference. The method of claim 6, It is further provided with a packing member having a plurality of engaging projections protruding to the bottom surface for tight coupling of the main body and the cage cover; The upper edge of the main body is formed with a recess for mounting the packing member, the recess is completely closed cage system having a plurality of coupling holes formed in a position corresponding to the engaging projection. The method according to claim 1 or 7, An air supply port mounted to the rear surface of the main body for supplying air into the housing, and an air discharge port for discharging the internal air to the outside; The air inlet and the air exhaust port are respectively coupled to the through hole formed in the rear surface of the main body and the first through-hole is formed in the groove formed in the center and the first bracket and the plurality of air inlet holes formed around the first through hole and , A second bracket having a second through hole in the center thereof and being press-bonded together with the first bracket to the through hole of the main body to fix the outer circumferential portion to maintain a sealing state; A movable member having an outer circumferential portion elastically supported by a spring on an outer side of the recess of the first bracket, a third through hole communicating with the first through hole at a central portion thereof, and a plurality of air inlet holes around the third through hole; , Sealing plate which is in close contact with the inner surface of the groove portion of the first bracket so as to seal the air inlet hole of the first bracket in conjunction with the movable member; Fully closed cage system including a sealing ring attached to the sealing surface of the sealing plate. The method of claim 8, The air inlet is mounted to the inside of the first bracket, to prevent the noise caused by the contact of the experimental animal, and further comprises a protective cap for preventing the penetration of this material, such as a rug into the air inlet. The method of claim 9, The air exhaust vent is mounted inside the first bracket, the hermetic cage system further comprises a cage exhaust filter including a low density filter for primarily filtering contaminants having a large particle size. The method of claim 10, The cage cover extends up and down and has a cylindrical flange with an opening therein; An opening / closing cap for opening and closing the upper portion of the cylindrical flange, a ventilation fixing plate mounted on the lower end of the cylindrical flange, a filter placed on the ventilation fixing plate, and an outer circumferential part thereof fixed to the filter so that the air can be filtered out. Fully closed cage system having a cage cover filter including a rotating plate that is pressed against the lock. A bucket including a tank having an opening formed on an inclined surface, a nozzle for allowing water to flow out by suction, and a through hole into which the nozzle is inserted, and a sealing stopper coupled to the opening of the tank; A feed container having a plurality of feed discharge slots formed at predetermined intervals and having a fixing flange extending from an upper edge thereof; A main body having an air supply port for supplying air and an air exhaust port for discharging the contaminated air to the outside, and a space for rearing the experimental animal mounted on the rear surface; A bucket receiving groove having an inclined surface formed at an angle corresponding to the inclined surface formed in the tank, and having a sealing coupling means mounted on the inclined surface so that the nozzle of the bucket is sealedly coupled, so that the fixing flange of the feed container is caught; Feed cage receiving port having a circumferential rim formed in the inner side and a flange protruding upward along the boundary, a cage cover having a fastening protrusion formed on the front and rear edges; A housing including a packing member coupled along an upper edge of the main body for hermetic coupling of the main body and the cage cover; Receptacle cover coupled to the flange of the feed container receiving port for blocking the access of air; It consists of a handle member having a top end hinged to the main body, and a fastening member having a bottom end hinged to the center portion of the handle member and a fastening groove at the top end in contact with the outer circumference of the cage cover when fastened to the cage cover, A pair of clamps for fastening to maintain the coupled state of the cage cover; Fully closed cage system comprising a cage cover filter including a filter for natural circulation in the air filtered state inside and outside the housing. The fully closed cage system according to claim 1, further comprising a cover covering the receiving port to block entry of contaminants through the receiving port in which the feed container is mounted. The method of claim 13, The bucket includes a nozzle for outflow of water by suction of the laboratory animal, the nozzle is inclined completely closed cage system.