KR20230119451A - Pet tower - Google Patents

Abstract

The present invention relates to a tower for companion animals. In the present invention, there is a rod assembly 400 having a plurality of rods 500 , 600 , and 700 having a variable length, and seat portions 918 and 920 may be installed on an outer surface of the rod assembly 400 . The scratchers 950a and 950b are rotatably positioned on the seat portions 918 and 920 so that when in use, the scratchers 950a and 950b adhere to the surfaces of the rods 500, 600 and 700, and when not in use, the sheet portions 918 and 920 ) can be in close contact with one surface of the The present invention may include a case in which an installation space is formed. A temperature control device 200 may be disposed in the case, and the temperature control device 200 may generate cold or warm air. Cold air or warm air may be transmitted to the seat portion through the rod assembly 400 .

Description

Pet tower {Pet tower}

The present invention relates to a tower for companion animals.

In general, a companion animal refers to an animal that mainly lives with people indoors, and various devices for breeding such companion animals in a healthy way have been developed. For example, cat towers, cat trees, cat wheels, and the like can be used as play facilities for cats.

In general, a cat tower or cat tree is an amusement facility that uses the habit of cats climbing or descending high places and enjoying hiding. These cat towers are often built as tall as towers for cats to play in. To this end, in the cat tower, a plurality of plate materials are fixed in layers to a pillar formed at a predetermined height, and a space in which a cat can hide is sometimes provided in the pillar.

For example, Korean Patent Registration No. 10-2198972 (Prior Document 1) discloses a cat tower that changes the structure of the cat tower by estimating the height and position preferred by the cat by analyzing the sensing information received from the pressure sensor. Publication Patent Publication No. 10-2020-0079210 (Prior Document 2) discloses a cat tower fixed to an existing window frame.

However, conventional cat towers only provide a play space for cats, and have limitations in not providing other functions. In particular, since the cat tower occupies a large volume indoors compared to other play equipment or play facilities, it is necessary to provide more diverse functions for the convenience of cats.

On the other hand, US Patent Publication US 2017/0027131 Al (Prior Document 3) and Chinese Patent Publication CN 107410072 A (Prior Document 4) disclose a technology for providing warmth through a heater to the inside of a cage in which a companion animal can stay . However, both of the technologies in Prior Art 3 and Prior Art 4 simply provide warmth to the inside of the empty space, and do not provide a play space for cats like a cat tower.

In addition, Korean Patent Publication No. 10-2021-0121624 (Prior Document 5) discloses a cat tower capable of adjusting height and rotation, and a stacked cat house is disclosed in Chinese Utility Model Publication CN201911160U (Prior Document 6).

The cat towers of Prior Art 5 and 6 can provide a cat tower capable of changing the height or shape, but in order to change the shape or height, the user has to manually reassemble the cat tower.

And, Korea Patent Publication No. 10-2019-0033860 (Prior Document 7) discloses a cat tower equipped with a scratcher to satisfy the scratching habit with claws according to the hunting instinct of a cat. However, there is a problem in that the scratcher is fixed and cannot cope with the situation according to the size of the cat or the growth of the cat. This is the same problem that occurs in Korean Patent Publication No. 10-2020-0145563 (Prior Document 8).

In addition, since the conventional cat tower is installed in a manner that is erected on the floor, the usable area of the floor is reduced, and there is also a disadvantage in that it is easy to interfere with other facilities.

(Prior Document 1) Korean Patent Registration No. 10-2198972 (Prior Document 2) Korean Patent Publication No. 10-2020-0079210 (Prior Document 3) US Patent Publication US 2017/0027131 Al (Prior Document 4) Chinese Patent Publication CN 107410072 A (Prior Document 5) Korean Patent Publication No. 10-2021-0121624 (Prior Document 6) Chinese Public Utility Model CN 201911160 U (Prior Document 7) Korean Patent Publication No. 10-2019-0033860 (Prior Document 8) Korean Patent Publication No. 10-2020-0145563

The present invention is to solve the problems of the prior art as described above, and an object of the present invention is to enable position adjustment of a scratcher used in a tower for companion animals.

An object of the present invention is to prevent the scratcher used in the companion animal tower from being visible from the outside when not in use.

An object of the present invention is to ensure that the installation state of the scratcher used in the companion animal tower is robust.

An object of the present invention is to provide a tower for companion animals capable of appropriately controlling ambient temperature so that companion animals feel comfortable.

Another object of the present invention is to provide a tower for companion animals whose height is adjusted by pushing or pulling a rod assembly.

Another object of the present invention is to provide a space for companion animals to stay on one side of the tower, and to control the temperature inside the space.

Another object of the present invention is to provide cold air or warmth to a plurality of seat parts disposed at different heights in a tower.

Another object of the present invention is to enable a tower for companion animals to be installed away from the floor.

According to a feature of the present invention for achieving the above object, the present invention can be installed in the scratcher of the rod assembly of the variable length rod assembly. The position of the scratcher may be changed while moving along with the length change of the rod assembly. Therefore, it can be used by changing the installation location according to the pet's physique or growth process.

In the present invention, a scratcher may be installed on a seat portion movably installed on a rod constituting a rod assembly. Therefore, while the scratcher moves on the rod assembly according to the movement of the seat part, the scratcher can be positioned at an optimal position for the companion animal to use.

In the present invention, the elastic force of the elastic member or the magnetic force of the magnet can be used so that the scratcher can be firmly fixed in use and storage conditions. The state in which the scratcher is in close contact with the surface of the rod or in close contact with one surface of the seat portion may be firmly maintained, so that the scratcher may not flow during use or storage.

The present invention may include a case having an installation space formed therein. A temperature control device may be disposed in the case, and the temperature control device may generate cold or warm air. Also, a rod assembly having an air flow path therein may be connected to the case. Accordingly, the temperature of the tower may be adjusted while cold air or warm air flows through the air passage.

The present invention relates to a rod assembly in which at least two rods are overlapped and connected to have a variable length, a seat portion installed on the rod and configured to be adjusted in position by movement of the rod, and installed on the side of the rod and centered on a rotational axis. It is rotatable at a predetermined angle and may include a scratcher provided with an out plate detachably on the base plate.

The present invention relates to a rod assembly in which at least two rods are overlapped and connected in a variable length and installed vertically, a seat portion installed on the rod so as to be movable in the longitudinal direction of the rod, and a rotational axis of the seat portion It is rotatable at a predetermined angle and may include a scratcher provided with an out plate detachably on the base plate.

The scratcher may be rotatable in a range between an outer surface of the rod and one surface of the seat portion.

When the scratcher approaches the outer surface of the rod, the base plate may face the outer surface of the rod, so that the outer plate may be exposed to the outside.

The scratcher may be rotatably installed on the seat part about the axis of rotation.

An elastic member may be installed on the rotating shaft so that the scratcher may adhere to the surface of the rod or one surface of the seat portion.

A magnet may be installed or a magnet and a metal member may be installed at positions corresponding to each other between the scratcher and the rod or the scratcher and the seat portion.

The length of the scratcher may be equal to or shorter than the length of the seat portion.

The surface of the out plate may be made of at least one of paper, fiber, and wood.

A seat lifting device for lifting the seat part may be installed inside the rod.

The seat lifting device includes a lifting driver installed inside the rod, a lifting bar lifted inside the rod by the lifting driver, and integrally provided with the lifting bar and connected to the seat portion through a lifting slot formed in the rod A lift bridge may be included.

The lifting driver may include a driving box, a lifting motor installed inside the driving box, and gears that transmit driving force of the lifting motor, and a worm is installed on a rotating shaft of the lifting motor to form a worm gear as one of the gears. can engage with

The lifting bar may be a rack gear.

The rod assembly may be composed of a plurality of rods continuously disposed from the case. Accordingly, the user can adjust the height of the rod assembly by pushing up or pulling down the rod assembly.

In addition, a housing space may be formed inside the case, and some of the air discharged from the temperature controller may be supplied to the housing space. Therefore, the thermostat can appropriately control the internal temperature of the tower so that companion animals can feel comfortable.

In addition, a rod discharge hole opening the air passage to the outside may be formed in the rod assembly. Since cold air or warm air can be discharged to the outside through the rod discharge hole, cold air or warm air can be provided to a companion animal sitting on the seat.

At this time, the upper end of the rod assembly may be opened in the direction of the case, and the lower end of the rod assembly may be opened to the outside. Therefore, it is possible to provide a comfortable temperature not only to companion animals staying inside the tower or to the seat portion, but also to companion animals located below the tower.

A duct guide may be disposed between the temperature controller and the rod assembly. At this time, a guide passage connecting an air outlet of the temperature controller and an upper end of the rod assembly may be formed inside the duct guide. Air may be distributed not only to the housing space but also to the air duct through the duct guide.

In addition, a duct fan for sucking in the air discharged from the temperature controller may be disposed above the rod assembly. The duct fan can effectively deliver cool air or warm air to the end of the rod assembly.

In addition, the temperature control fan provided in the temperature control device and the duct fan may be disposed in directions orthogonal to each other. The temperature control fan and the duct fan may transfer cool air or warm air in different directions.

In addition, a guide outlet of the duct guide and a part of the housing space may be opened toward a duct fan disposed above the rod assembly, respectively. Accordingly, since the duct fan can suck in air in the housing space as well as the duct guide and transfer it downward, cool air or warm air can be more smoothly delivered to the lower end of the tower.

In addition, since the duct fan sucks in the air in the housing space, the air inside the housing space can be continuously discharged by the duct fan without being stagnant, and the air inside the housing space can be purified.

A heat insulating member may be disposed between the outer case and the inner case. A part of the temperature control device may be covered by the heat insulating member. Through this, it is possible to increase the insulation effect of the temperature controller.

In addition, the inner case and the temperature controller may be disposed in left and right directions with an inner wall of the heat insulating member interposed therebetween. In this way, the protruding distance of the case from the wall surface can be reduced.

A fan housing may be disposed in the air passage inside the rod assembly, the duct fan may be disposed inside the fan housing, and the fan housing may fill a gap between an inner surface of the rod assembly and the duct fan.

In addition, an internal sensor for measuring temperature or humidity inside the housing space may be disposed inside the housing space. An external sensor for measuring temperature or humidity outside the case may be disposed in the case. The control unit may automatically control the temperature of the tower through the temperature measured by the internal sensor and the external sensor.

In addition, the case may include an outer case and an inner case disposed inside the outer case and having a housing space formed therein. At this time, the temperature controller may discharge air into the housing space.

The rod assembly may include a first rod connected to the case and a second rod extending from the first rod. In this case, the first rod and the second rod may be disposed to overlap each other. Accordingly, while the first rod and the second rod overlap or unfold each other, the overall length of the rod assembly may be varied.

In addition, a sealing member may be provided at a portion where the first rod and the second rod are connected to each other. Such a sealing member may prevent air from leaking between the first rod and the second rod.

The tower for companion animals according to the present invention as examined above may have at least one or more of the following effects.

In the tower for companion animals of the present invention, the scratcher may be moved according to the elevation of the rod of the rod assembly. Therefore, the position of the scratcher can be adjusted according to the size of the companion animal, so that the companion animal can comfortably use the scratcher.

In the tower for companion animals of the present invention, the scratcher may be rotated by a predetermined angle with respect to the rod assembly or the seat portion installed therein, so as to be in close contact with the surface of the rod or one surface of the seat portion. In particular, when the scratcher is in close contact with one surface of the seat portion, the scratcher cannot be used, so that only a specific companion animal can use the scratcher.

In addition, in the companion animal tower of the present invention, an elastic member is placed on the rotating shaft or the magnetic force of the magnet is used so that the scratcher is installed on the surface of the rod or on one side surface of the seat portion. Therefore, the state in which the scratcher is installed on the surface of the rod is solid, so that the scratcher does not flow during use, giving satisfaction to the companion animal, and the companion animal cannot arbitrarily release the state in which the scratcher is in close contact with one surface of the seat part. Scratcher management can be done according to the administrator's intention.

The temperature of the companion animal tower of the present invention may be controlled by a temperature controller. These thermostats can appropriately control the temperature inside and around the tower so that companion animals can feel comfortable. Therefore, the present invention can provide a comfortable environment for companion animals.

In addition, the tower for companion animals of the present invention is provided with a rod assembly composed of a plurality of rods, so that the height of the tower can be formed. At this time, the plurality of rods can adjust the height of the tower while the length is varied. Therefore, since the height of the companion animal tower can be varied according to the habit of the companion animal or the installation environment, the companion animal tower of the present invention has a high compatibility effect.

In addition, by adjusting the height of the tower for companion animals, there is an effect of arousing interest in companion animals. In particular, since the user can adjust the height of the tower by pushing up or pulling down the rod assembly, the height of the tower can be easily adjusted.

In addition, a space (housing space) in which companion animals can stay may be provided at the top of the tower according to the present invention, and the internal temperature of the housing space may also be controlled by a thermostat. Accordingly, the present invention can provide an environment in which companion animals can feel more comfortable in a housing space.

In addition, according to the present invention, since the inside of the tower and the temperature of the seat provided in the tower can be adjusted, an appropriate temperature for companion animals can be formed even if the temperature of the entire space in which the tower is installed is not adjusted. Accordingly, energy consumption can be reduced because only the temperature of the tower needs to be adjusted, not the entire space where the tower is installed.

At this time, the control fan provided in the temperature control device can discharge cold air or warm air into the housing space, and the duct fan can discharge cold air or warm air to the lower part of the rod assembly forming the air flow path. Accordingly, not only the housing space but also the temperature of the entire interior of the rod assembly can be evenly controlled.

In addition, the duct fan can suck not only the air directly discharged from the temperature controller, but also the air inside the housing space and deliver it to the lower part of the rod assembly. Accordingly, since the air inside the housing space can be continuously discharged without being stagnant, the air inside the housing space can be purified.

And, in the present invention, the rod assembly connected to the thermostat can be extended along the height direction of the tower, and the air cooled or heated by the thermostat can move through the inside of the rod assembly. Therefore, cold air or warm air can be transmitted to the lower end of the tower without leaking to the outside, and the temperature can be evenly controlled along the height direction of the tower.

In the present invention, the position of the seat part can be changed by moving along with the movement of the rod of the rod assembly, or the seat part can be moved relative to the rod by the seat lifting device, so that the position of the seat part can be set in various ways. This allows the companion animal tower to be used according to the size or growth level of the companion animal, greatly increasing the effectiveness of the companion animal tower.

And, in the present invention, the case may be installed on a wall or ceiling. In this way, the companion animal tower can be installed in a state away from the floor (ground). When the companion animal tower is spaced apart from the floor, the usable area of the floor can be increased, and interference with other facilities can be prevented.

1 is a perspective view showing an embodiment of a tower for companion animals according to the present invention.
Figure 2 is a perspective view showing a state in which the door is opened in one embodiment of the present invention.
Figure 3 is an exemplary view showing an embodiment of the present invention installed indoors.
Figure 4 is a side view showing one embodiment of the present invention.
Figure 5 is a perspective view of one embodiment of the present invention viewed from below.
Figure 6 is a perspective view showing the disassembled parts constituting the case of one embodiment of the present invention.
Figure 7 is an exploded perspective view of the parts constituting the case of one embodiment of the present invention seen from a different angle from Figure 6;
Figure 8 is a cross-sectional view taken along the line VIII-VIII' of Figure 1 showing a case portion of one embodiment of the present invention.
Figure 9 is a perspective view showing the configuration of a heat insulating member constituting one embodiment of the present invention.
Figure 10 is a perspective view showing a state in which the temperature controller constituting one embodiment of the present invention is disassembled from the case.
Figure 11 is a perspective view showing a duct guide constituting an embodiment of the present invention.
12 is a perspective view showing structures of an inner case and a door constituting one embodiment of the present invention;
13 is a cross-sectional view showing a closed state of a door constituting one embodiment of the present invention.
14 is a cross-sectional view showing an open state of a door constituting one embodiment of the present invention.
Fig. 15 is a cross-sectional view along the line XV-XV'.
16 is an enlarged cross-sectional view of the structure of the upper end of the case and the rod assembly in FIG. 15;
17 is a cross-sectional view of the lower portion of FIG. 8;
18 is a perspective view showing a state in which the upper end of the rod assembly and the duct fan constituting one embodiment of the present invention are disassembled from each other;
19 is a perspective view showing configurations of a temperature controller and a rod assembly constituting one embodiment of the present invention;
20(a) to 20(c) are operational state diagrams sequentially showing how the total length of the rod assembly constituting one embodiment of the present invention is reduced.
21 is a perspective view showing the configuration of a rod assembly constituting one embodiment of the present invention.
Figure 22 is a perspective view showing the configuration of a rod assembly constituting one embodiment of the present invention from a different angle from Figure 21;
23 is a perspective view showing the configuration of a first rod constituting one embodiment of the present invention;
24 is a cross-sectional view showing the configuration of a first rod constituting one embodiment of the present invention.
25 is a cross-sectional view showing a state in which a rod heater constituting one embodiment of the present invention is disposed on a first rod.
26 is a cross-sectional view showing a state in which a rod heater constituting another embodiment of the present invention is disposed on a first rod.
27 is a perspective view showing the configuration of a rod heater constituting one embodiment of the present invention.
28 is a perspective view showing the configuration of a second rod constituting one embodiment of the present invention;
29 is a cross-sectional view showing the configuration of a second rod constituting one embodiment of the present invention.
30 is a perspective view showing the configuration of a third rod constituting one embodiment of the present invention;
31 is a cross-sectional view showing the configuration of a third rod constituting one embodiment of the present invention.
32 is a cross-sectional view showing the structure of a seat lifting device disposed inside a rod assembly constituting one embodiment of the present invention.
33 is a cross-sectional view showing a state in which a seat portion is raised by a seat elevating device constituting an embodiment of the present invention.
34 is a perspective view showing the structure of a lift housing constituting the seat lift device shown in FIG. 33;
Fig. 35 is a perspective view showing the structure of the elevating housing constituting the seat elevating device shown in Fig. 33 from a different angle from Fig. 34;
36 is a cross-sectional view showing the structure of a seat lifting device and a seat part after removing the first rod constituting one embodiment of the present invention.
37 is a cross-sectional view showing the lower structure of a seat lifting device constituting one embodiment of the present invention.
38 is a perspective view showing the structure of a seat lifting device and a seat part after removing the rod assembly constituting one embodiment of the present invention;
Figure 39 is a perspective view showing the structure of the seat lifting device and the seat part from a different angle from Figure 38, with the rod assembly constituting one embodiment of the present invention removed.
40 is a cross-sectional view showing the internal structure of a first rod including a seat elevating device constituting an embodiment of the present invention.
41 is a perspective view showing a gear part of a rod assembly constituting one embodiment of the present invention;
42 is a cross-sectional view showing a gear portion of a rod assembly constituting one embodiment of the present invention.
43 is a perspective view showing a drive box of a rod assembly constituting one embodiment of the present invention;
44 is a perspective view showing a first gear housing among driving boxes of a rod assembly constituting an embodiment of the present invention;
45 is a perspective view showing a second gear housing among drive boxes of a rod assembly constituting one embodiment of the present invention;
46 to 47 are operating state diagrams each showing how the scratcher constituting one embodiment of the present invention is operated.
48 is a perspective view showing another embodiment of a tower for companion animals according to the present invention.
49 is a perspective view showing another embodiment of a tower for companion animals according to the present invention.

Hereinafter, some embodiments of the present invention will be described in detail through exemplary drawings. In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing an embodiment of the present invention, if it is determined that a detailed description of a related known configuration or function hinders understanding of the embodiment of the present invention, the detailed description will be omitted.

The present invention relates to a tower for companion animals (hereinafter referred to as "tower"). The tower of the present invention can provide a space and a foothold for companion animals to stay or move, and can provide an appropriate temperature environment for companion animals. The tower of the present invention can be used for several types of companion animals. For example, the tower of the present invention can be used not only for cats but also for various animals such as dogs, squirrels, and birds.

At this time, cooled air (hereinafter referred to as 'cold air') or heated air (hereinafter referred to as 'warm air') may be supplied to the tower. In the tower, cool air or warm air generated by the thermostat 200 to be described below may be delivered to the lower part of the tower along the rod assembly 400 as well as the housing space S of the tower. Hereinafter, among the structures of the present invention, a structure for controlling temperature and a flow structure of cold air/warm air will be mainly described.

Referring to FIG. 1 , a housing module 100 may be disposed above the tower of this embodiment. The temperature controller 200 may be installed in the housing module 100 . A housing space S may be formed inside the housing module 100 . In this embodiment, the housing module 100 is located at the top of the tower, but unlike this, the housing module 100 may be disposed at the middle or bottom of the tower.

The housing module 100 may also be viewed as a case 100 . The housing module 100 may be installed with the temperature control device 200 and may have a housing space S, which is a separate space, inside the housing module 100, so that the housing module 100 is a kind of case 100. it can be seen

In this embodiment, the housing module 100 (i) can be a part where the temperature controller 200 is installed, (ii) can provide the housing space (S) for companion animals, (iii) It can also serve as a fixture to keep the tower fixed in the installation position.

As shown in FIGS. 1 and 2 , the housing module 100 may have a substantially hexahedral shape, but the shape of the housing module 100 may be variously modified. The housing module 100 may have a curved exterior or may have a regular hexahedron shape. The shape and volume of the space formed inside the housing module 100 may be changed according to the outer shape of the housing module 100 .

2 shows the door 150 constituting the housing module 100 in an open state. In FIG. 2, the entrance of the housing space (S) is opened so that the housing space (S) is exposed to the outside. When the door 150 is opened, the companion animal may enter the housing space S through the entrance of the housing space S. The door 150 may be automatically opened and closed by a door opening and closing device to be described below. As such, in this embodiment, since the housing space (S) is provided at the highest position of the tower, it is possible to provide comfort to companion animals such as cats who have a habit of going up to high places.

A rod assembly 400 may extend below the housing module 100 . The rod assembly 400 may extend downward of the housing module 100 . The height of the rod assembly 400 may be higher than that of the housing module 100 . The rod assembly 400 may be a position where a seat assembly 900 to be described below is fixed. Also, air may flow through the inside of the rod assembly 400 .

In this embodiment, the rod assembly 400 may be composed of a plurality of rods 500, 600, and 700. In addition, a plurality of seat assemblies 900a to 900e may be disposed on the plurality of rods 500 , 600 , and 700 at different heights. In this embodiment, the rod assembly 400 includes a total of three rods 500, 600, and 700, but, unlike the rod assembly 400, two or four or more rods may be included. These rods 500, 600, and 700 may be made of a metal material. When the rods 500 , 600 , and 700 are made of a metal material with high thermal conductivity, the companion animal can feel cold or warm by directly bringing their skin into close contact with the rods 500 , 600 , 700 .

Referring to Figure 3, it is shown that the tower of this embodiment is installed. As shown in FIG. 3 (a), the tower may be installed so as to be in close contact with the ceiling (C), or may be installed so as to be separated from the ceiling (C) as shown in FIG. 3 (b). In this embodiment, the tower may be installed on a wall surface (W) or installed on a ceiling (C) through a bracket module 190 to be described below. When the tower is installed to be spaced apart from the ceiling (C) as shown in FIG. 3 (b), the upper surface of the housing module 100 may also become a seating portion for companion animals.

The tower in this embodiment may be spaced apart from the floor (ground, G). As the tower is installed on the wall (W) or ceiling (C), the lower end of the tower can be separated from the floor (G). Accordingly, the usable area of the floor G may be increased. Of course, the lower end of the tower may be supported on the floor (G). Reference numeral K1 is the distance the tower is spaced from the floor (G), and K2 represents the distance from the ceiling (C).

Referring to Figure 4, a side view of the tower is shown. A rod assembly 400 may extend below the tower. The rod assembly 400 may extend in the vertical direction, that is, in the height direction of the tower. 4 shows a state in which the length of the rod assembly 400 is the longest, the length adjustment structure of the rod assembly 400 will be reviewed below.

In this embodiment, a total of five seating surfaces may be provided on the tower. The seating surface, except for the housing space (S), may mean a place through which companion animals stay or move. The seating surfaces may be formed on upper surfaces of the seat parts 918 and 920 to be described below. The seat portions 918 and 920 may be disposed at different heights. The seat parts 918 and 920 may be further divided into a step station 918 and a seat station 920.

In addition, in this embodiment, the tower may be provided with scratchers 950a and 950b. The scratchers 950a and 950b may provide companion animals with a scratching distance or increase frictional force when companion animals step on them. In particular, among companion animals, cats have a habit of scratching their claws against a specific object, and the scratchers 950a and 950b become objects that cats can scratch. The scratchers 950a and 950b may be configured in plurality. Referring to FIG. 1, one of the two scratchers 950a and 950b is shown in an unfolded state, and the other is shown in a folded state. For reference, the scratchers 950a and 950b may be used in an unfolded state. The detailed structure of the scratchers 950a and 950b will be described again below.

The rod assembly 400 may be divided into three parts. As shown in FIG. 4 , the first area A may be disposed right below the housing module 100 and is at the highest position among the rod assemblies 400 . And, below the first area, the second area (B) and the third area (C) may be sequentially followed. The first zone (A) corresponds to the height of the first rod 500 to be described later, the second zone (B) corresponds to the height of the second rod 600, and the third zone (C) It may correspond to the height of the third rod 700. As described above, the height of the rod assembly 400, which is the total height of the first to third areas, may be variable. In addition, in the process of varying the height of the rod assembly 400, the height of the seat portions 918 and 920 may also be varied.

Referring to FIG. 5, a view of the tower from below is shown. As can be seen, the outlet 715 of the air flow path may be formed at the lower end of the tower. More precisely, the lower end of the rod assembly 400 is opened downward so that the outlet 715 of the air flow path can be formed. Thus, cold or warm air can be supplied to companion animals staying at the bottom of the tower.

In this embodiment, a plurality of the sheet assemblies 900a to 900e may be disposed at different heights in the tower. As shown in FIG. 5 , the plurality of seat assemblies 900a to 900e may be disposed at different heights between the lower end of the rod assembly 400 and the case 100 . Accordingly, the companion animal may use the plurality of seat assemblies 900a to 900e as stairs when going to the case 100 .

6 and 7 show parts constituting the housing module 100 in an exploded state. The housing module 100 may include a case cover 110 constituting an outermost surface of the housing module 100, and an outer case 120 and an inner case ( 130) can be accommodated. In addition, a heat insulating member 160 may be disposed between the outer case 120 and the inner case 130 .

Here, the case cover 110 , the outer case 120 , the inner case 130 , and the heat insulating member 160 can be regarded as constituting one case 100 . A housing space (S) is provided inside the case 100, and a temperature control device 200 to be described later may be disposed.

Looking at the case cover 110 first, the case cover 110 may have a substantially hexahedral shape. The case cover 110 may configure the exterior of the housing module 100, and when the housing module 100 is installed on a wall surface (W) or ceiling (C), the installation surface and come into contact Of course, the housing module 100 may be fixed to the installation position through the bracket module 190, but the bracket module 190 may be omitted and the case cover 110 may be directly fixed to the installation surface. For stable fixation, the case cover 110 may be made of a metal material.

The case cover 110 may include a lower cover plate 111 , a cover side plate 113 , a cover upper plate 116 , and a cover back plate 118 . The front surface of the case cover 110 is open, and a cover opening hole 112 in which a connection flange 169 of the heat insulating member 160 to be described below is disposed may be formed in the lower cover plate 111. The cover opening hole 112 extends to the front surface of the case cover 110 and may open forward.

Cover side plate holes 114 and 115 may be opened in the cover side plate 113 . The first side hole 114 among the cover side plate holes 114 and 115 can reduce the total weight of the case cover 110 and the housing module 100, and a display (not shown) or the like may be disposed therein. The temperature controller 200 may be disposed in the second side hole 115 .

A cover top plate hole 117 may be opened in the cover top plate 116 . A control unit 180 to be described later may be exposed through the cover upper plate hole 117 . The controller 180 may be accessed through the hole 117 of the cover top plate. Of course, the cover top plate hole 117 may be omitted, and the entire cover top plate 116 may have a blocked structure.

An outer case 120 may be disposed inside the case cover 110 . The outer case 120 may cover the inner case 130 and the heat insulating member 160 and may form a skeleton of the housing module 100 . The outer case 120 may have a hexahedral shape like the case cover 110, but its shape and size may be changed.

The lower portion of the outer case 120 may be opened. The bottom and rear surfaces of the outer case 120 may be omitted, and the case opening 122 may be formed at the omitted portion. The inner case 130 and the heat insulating member 160 may be disposed in the case opening 122 . Also, the front surface of the outer case 120 may be opened to form a front open portion 124 . The front opening part 124 may be a part where the door 150 is disposed.

An outer plate hole 125 may be formed in the outer plate 123 of the outer case 120 . The temperature controller 200 may be disposed in the outer plate hole 125 . In addition, an outer top plate hole 127 may be opened in the outer top plate 126 . The controller 180 may be exposed through the outer top plate hole 127 . The controller 180 can be accessed through the outer top plate hole 127 and the cover top plate hole 117 described above. Of course, the outer top plate hole 127 may be omitted, and the entire outer top plate 126 may have a blocked structure.

As shown in FIG. 6 , a door support end 129 may be provided at a front lower portion of the outer case 120 . The door support end 129 may be provided at a lower front portion of the outer case 120, that is, at a lower portion of the front opening portion 124. The door support end 129 may protrude forward along the lower end of the outer case 120 . The door support end 129 may serve to support the door 150 when the door 150 is opened.

An inner case 130 may be disposed inside the outer case 120 . The inner case 130 may form the housing space S therein. Also, the outer case 120 may be connected to the temperature controller 200 so that the air discharged from the temperature controller 200 is delivered. The inner case 130 may be disposed inside the outer case 120 by having a smaller size than the outer case 120 .

The inner case 130 may include an inner lower plate 131 , an inner side plate 133 , an inner upper plate 136 , and an inner thick plate 138 . A front surface of the inner case 130 may be opened to become an entrance 134 , and the opened entrance 134 may be shielded by the door 150 . The housing space (S) may be formed inside surrounded by the inner lower plate 131, the inner side plate 133, the inner upper plate 136, and the inner thick plate 138.

A part of the inner lower plate 131 may be opened. Referring to FIG. 8 , a lower open hole 132 may pass through the inner lower plate 131 , and a communication cap DC may be inserted into the lower open hole 132 . The communication cap DC blocks the lower open hole 132, and air can flow through the cap hole DC' formed in the communication cap DC. That is, it can be seen that the communication cap DC forms a communication passage through the cap hole DC'. Through the communication passage, the air in the housing space (S) can move downward, that is, in the direction of the rod assembly (400). Alternatively, the communication cap DC may be omitted and the cap hole DC' may be a part of the lower open hole 132 formed directly on the inner lower plate 131 .

Although not shown, a dust filter may be provided in the communication cap DC. The dust filter may filter foreign substances such as dust or hair mixed in the air passing through the cap hole DC' of the communication cap DC. Since foreign substances such as hair discharged by companion animals staying inside the housing space S are filtered out by the dust filter, foreign substances can be prevented from being transferred to the duct fan 300. The dust filter may be replaced after being separated from the communication cap DC.

A door mounting portion 134a (see FIG. 10) may be provided at a lower portion of the entrance 134. The door mounting portion 134a may be a portion extending below the entrance 134 . The door rotation shaft 153 of the door 150 may be installed in the door mounting part 134a. More precisely, a shaft installation portion 138 (see FIGS. 10 and 12) is provided in the door mounting portion 134a, and the door rotation shaft 153 may be inserted into the shaft installation portion 138. The shaft installation parts 138 may be provided at both ends of the door mounting part 134a, and both ends of the door rotation shaft 153 may be fitted into the pair of shaft installation parts 138, respectively.

Referring to FIG. 6 , a side communication hole 135 may be opened in the inner side plate 133 of the inner case 130 . The side communication hole 135 may be a portion where the temperature controller 200 is disposed. A duct guide 260 to be described later may be disposed in the side communication hole 135 . The air discharged from the temperature controller 200 may be delivered to the housing space S via the duct guide 260 .

Referring to FIG. 10 , a motor mounting portion 137 may be provided in the inner case 130 . The motor mounting part 137 may be a part where the opening/closing motor 140 to be described below is mounted. The motor mounting part 137 may be formed by opening a part of the inner side plate 133 of the inner case 130 . The motor mounting part 137 may be provided at a position adjacent to the door mounting part 134a. In this embodiment, the motor mounting part 137 is disposed on one side of the pair of inner side plates 133, and more precisely, it may be installed on the side of the inner side plate 133 where the temperature controller 200 is disposed. Unlike this, the motor mounting part 137 may be provided on the inner side plate 133 corresponding to the opposite side of the temperature controller 200 .

Referring to FIG. 12 , a door stopper 139 may be provided in the inner case 130 . The door stopper 139 may serve to limit the maximum rotation angle of the door 150 when the door 150 is opened through rotation. The door stopper 139 may limit the rotation angle of the door 150 by engaging the rotation driving unit 155 provided on the door 150 .

The door stopper 139 may protrude from the inner side plate 133 of the inner case 130 . More precisely, the door stopper 139 may protrude from an inner surface of the inner side plate 133 toward the housing space (S). The door stoppers 139 may be provided on both inner side plates 133 in directions facing each other. The pair of door stoppers 139 may respectively hang the pair of rotation driving units 155 provided on the door 150 . More precisely, the connection arm 156 connected to the rotary driving unit 155 and the door stopper 139 may interfere with each other.

The door stopper 139 may have a substantially triangular or sectoral shape. The flat section formed on the side surface of the door stopper 139 comes into contact with the locking surface 156' provided on the connection arm 156 of the rotary drive unit 155 of the door 150 to prevent rotation of the door 150. can be limited The door stopper 139 may be disposed inside the rotation driving unit 155 having a substantially circular arc shape, and may not interfere with the rotation driving unit 155 during rotation of the rotation driving unit 155 . When the door stopper 139 has a fan shape, a curved portion of the door stopper 139 may come into contact with the rotation driving unit 155 to guide rotation of the rotation driving unit 155 .

An opening/closing motor 140 may be mounted on the inner case 130 . The opening/closing motor 140 may provide driving force for rotating the door 150 . The opening/closing motor 140 may be disposed on the motor mounting part 137 of the inner case 130 . The opening/closing motor 140 may be fastened to an edge of the motor mounting portion 137 using fasteners such as bolts (not shown). The opening/closing motor 140 may constitute a door opening/closing device together with the rotation driving unit 155 of the door 150 .

An opening/closing gear 145 may be coupled to the opening/closing motor 140 . The opening/closing gear 145 is for rotating the door 150 and can be rotated by the opening/closing motor 140 . The opening/closing gear 145 may protrude through the motor mounting portion 137 . When the opening/closing gear 145 rotates, the rotation driving unit 155 of the door 150 engaged with the opening/closing gear 145 may rotate.

More precisely, as shown in FIG. 12, the drive gear 155a of the rotational driving unit 155 is engaged with the opening/closing gear 145, and the rotational driving unit 155 moves along with the rotation of the opening/closing gear 145. can rotate That is, the opening/closing gear 145 can be viewed as a kind of driven gear, and the rotary drive unit 155 can be viewed as a gear for deceleration.

At this time, it is preferable that the gear ratio between the opening/closing gear 145 and the driving gear tooth 155a is 0.2 to 0.5. That is, deceleration is achieved through the opening/closing gear 145 and the driving gear teeth 155a, and the door 150 can be opened and closed more smoothly while rotating. When the gear ratio is less than 0.2, the rotational speed of the door 150 is too slow, and when it exceeds 0.5, it becomes too fast and it is difficult to generate sufficient rotational force to open and close the door 150.

A door 150 may be coupled to the inner case 130 . The door 150 may serve to open and close the entrance 134 of the housing space (S). When the door 150 is closed, the housing space (S) can be an enclosed space, and when the door 150 is opened, the entrance 134 of the housing space (S) is opened so that companion animals can enter and exit. . For reference, the door 150 is shown in a closed state in FIG. 1 , and the door 150 is shown in an open state in FIG. 2 .

The door 150 may form a skeleton of a substantially plate-shaped door body 151 . And the door body 151 can be opened and closed through rotation. In this embodiment, the door 150 may be rotatably coupled to the inner case 130 and may be opened or closed through rotation. Of course, unlike this, the door 150 may be opened and closed in a sliding manner. Also, the door 150 may be configured in plurality.

A structure for rotating the door 150 is shown in FIGS. 12 to 14 . A door rotation shaft 153 may be provided in the door 150 . The door rotation shaft 153 may have an elongated structure extending along one edge of the door body 151 . Both ends of the door rotation shaft 153 may be inserted into the shaft installation part 138 of the inner case 130, respectively. The entire door 150 may be rotated around both ends of the door rotation shaft 153 .

A rotation driving unit 155 may be provided on the door body 151 . The rotary driving unit 155 may be provided at one edge portion of the door body 151 . More precisely, the rotary actuator 155 may be provided at both ends of the door rotation shaft 153 provided on the door body 151 , respectively. The rotary driving unit 155 interlocks with the opening/closing motor 140 so that the door 150 can be opened and closed.

The rotary driving unit 155 may have a substantially circular arc shape. Also, both ends of the rotary drive unit 155 may be connected to the door body 151 and the door rotation shaft 153, respectively. One end of the rotary drive unit 155 may be directly connected to the door body 151, and the other end of the rotation drive unit 155 may be connected to the door rotation shaft 153 through a connection arm 156.

A driving gear tooth 155a may be provided on the surface of the rotary driving unit 155 . The driving gear 155a engages with the opening/closing gear 145 to enable rotation of the rotary driving unit 155 . When the opening/closing motor 140 operates, the entire door 150 may be rotated while the driving gear teeth 155a engage with the opening/closing gear 145 to rotate. At this time, since the opening/closing gear 145 is rotatable in both directions, the rotary driving unit 155 can also be rotated in both directions. Non-explained numeral 155b denotes a rotation space that is an empty space inside the rotation drive unit 155.

A connection arm 156 provided on one side of the rotation drive unit 155 may connect the rotation drive unit 155 and the door rotation shaft 153 . The connection arm 156 may have a bar shape extending in approximately one direction. The connection arm 156 may interfere with the door stopper 139 while the rotary drive unit 155 is being rotated. When the locking surface 156' of the connection arm 156 interferes with the door stopper 139, the door 150 cannot rotate any further.

Referring to FIG. 13 , the door 150 is shown in a closed state. In this state, when the opening/closing gear 145 rotates clockwise (direction of arrow 1), the rotary driving unit 155 meshed with the opening/closing gear 145 may rotate counterclockwise (direction of arrow 2). As the door body 151 rotates in a counterclockwise direction (direction of arrow 3) together with the rotary driving unit 155, the door 150 may be switched to an open state. Here, reference numeral X denotes the center of rotation of the door rotation shaft 155.

14 shows a state in which the door 150 is fully opened. In the process of opening the door 150, the door stopper 139 may interfere with the locking surface 156' of the connection arm 156, and thus the rotation angle of the door 150 may be limited. . In this embodiment, the door 150 may be opened by approximately 90 degrees. Referring to FIG. 14 , a state in which the door body 151 is supported by the door support end 129 of the outer case 120 can be seen. That is, the door 150 may be supported in an open state by the door support end 129 together with the door stopper 139 . Further, when the opening/closing gear 145 rotated by the opening/closing motor 140 is rotated counterclockwise with reference to FIG. 14 , the door 150 may be switched to a closed state again.

As described above, in the present embodiment, the door 150 is coupled to the inner case 130 , but otherwise, the door 150 may be coupled to the outer case 120 or the case cover 110 . Also, the door 150 may be omitted and the housing space S may always remain open.

At least the inside of the door body 151 of the door 150 may be filled with an insulating material. This is to ensure better thermal insulation of the housing space (S). A buffer member (not shown) may be provided between the front surface of the door body 151 and the door support end 129 . The buffer member may be the door support end 129 or a coating layer made of a material having elasticity formed on the front surface of the door body 151 corresponding to the door support end 129 . Alternatively, the buffer member may be, for example, a torsion spring. In this way, when an elastic member is placed between the door body 151 and the door support end 129, shock generated when a companion animal lands on the door 150 can be reduced.

Meanwhile, a heat insulating member 160 may be disposed between the outer case 120 and the inner case 130 . The heat insulating member 160 may be formed by filling a foamed liquid in the heat insulating space, which is an empty space between the outer case 120 and the inner case 130, or a heat insulating member 160 made of a separate material. ) may be disposed between the outer case 120 and the inner case 130 . The heat insulating member 160 may be made of a material having high heat insulating properties such as Styrofoam.

Referring to FIG. 8 , the housing space S and the temperature controller 200 may be disposed in left and right directions with the inner wall of the heat insulating member 160 interposed therebetween. In this case, both the housing space (S) and the temperature controller 200 may be surrounded by a single heat insulating member 160 . In addition, since the housing space S and the thermostat 200 are disposed in the left and right directions, the distance at which the entire case 100 protrudes from the wall surface W is relatively reduced compared to when they are disposed in the front and rear directions. can

Like the outer case 120 and the inner case 130, the heat insulating member 160 may have a substantially hexahedron shape. The heat insulating member 160 may include a heat insulating lower plate 161, an insulating side plate 163, an insulating upper plate 166 (see FIG. 9), and a heat insulating thick plate 168 (see FIG. 7). The heat insulating member 160 may surround a portion of the temperature controller 200 and prevent cold air or warm air generated from the temperature controller 200 from leaking to the outside.

As shown in FIG. 6 , a lower connection hole 162 may be formed in the insulating lower plate 161 . The lower connection hole 162 may be connected to the lower open hole 132 of the inner case 130 described above. Cold air or warm air may be transmitted toward the rod assembly 400 through the lower connection hole 162 . A connection flange 169 to be described below may be provided below the lower connection hole 162 .

A front surface of the heat insulating member 160 may be opened. The open heat insulation entrance 164 of the heat insulation member 160 may be opened at a position corresponding to the entrance 134 of the inner case 130 . Therefore, the insulated entrance 164 can also be opened and closed by the door 150 .

A heat insulating side plate hole 165 may be formed in the heat insulating side plate 163 of the heat insulating member 160 . A second control fan F2 of the temperature controller 200 may be disposed in the heat insulation side plate hole 165 . The air discharged from the second control fan F2 may be supplied to the housing space S through the heat insulation side plate hole 165 and the side communication hole 135 of the inner case 130 . In addition, some of the air discharged by the second control fan F2 may be supplied downward, that is, toward the rod assembly 400, by the duct guide 260.

Referring to FIG. 8 , an installation space 165a may be formed in the heat insulating side plate 163 of the heat insulating member 160 . The installation space 165a can be seen as a kind of empty space. The temperature controller 200 may be disposed in the installation space 165a. The first control fan (F1) and the second control fan (F2) constituting the temperature controller 200 have a pair of heat insulation side plate holes 165 opened at the rear and front of the installation space 165a, respectively. can be exposed through Also, components constituting the thermostat 200, such as a thermoelectric element, a heat sink 214, and a cold sink 218, may be located inside the installation space 165a.

Referring to FIG. 9 , a motor mounting groove 167 may be provided in the heat insulating member 160 . The motor mounting groove 167 may have a structure recessed inward from the heat insulating side plate 163 . The motor mounting groove 167 may be a portion into which the opening/closing motor 140 is inserted. The motor mounting groove 167 may be formed only on one side where the heat insulating side plate hole 165 is formed among the pair of heat insulating side plates 163 facing each other. The opening/closing motor 140 may be inserted into the motor mounting groove 167 and fixed to the motor mounting portion 137 of the inner case 130 .

A connection flange 169 may be provided below the heat insulating member 160 . The connection flange 169 may be formed to further extend downward from the lower heat insulating plate 161 of the heat insulating member 160 . The connection flange 169 may be formed in a substantially cylindrical shape. In this embodiment, the connection flange 169 is provided under the heat insulating member 160, but the connection flange 169 may be part of the outer case 120 or the inner case 130.

Referring to FIG. 8 , the connection flange 169 may be disposed under the communication cap DC. The connection space 169a provided inside the connection flange 169 may be connected to the cap hole DC′ of the communication cap DC. At the same time, the connection flange 169 may also be connected to the second guide outlet 263b of the duct guide 260. Accordingly, air may be introduced into the connection space 169a through the cap hole DC', and air may also be introduced through the second guide outlet 263b.

A duct fan 300 provided above the rod assembly 400 may be disposed in the connection space 169a of the connection flange 169 . The duct fan 300 may suck air discharged through the second guide outlet 263b of the duct guide 260 and transfer it downward, that is, toward the lower end of the rod assembly 400 .

Meanwhile, a controller 180 may be disposed in the housing module 100 . The controller 180 may control the temperature controller 200 and the door opening/closing device. The control unit 180 may include a printed circuit board, and a power supply unit (not shown) for supplying power may be connected to the control unit 180 . In this embodiment, the controller 180 may be disposed on the inner top plate 136 of the inner case 130 . As described above, the controller 180 can be accessed through the outer top plate hole 127 and the cover top plate hole 117 .

An external sensor 183 may be connected to the controller 180 . The external sensor 183 may measure the temperature and humidity of external air. Here, the outside air may mean air in a space where the tower is installed. If the tower is installed indoors, the external sensor 183 can measure the air condition in the indoor space.

The external sensor 183 may be disposed on an outer surface of the inner top plate 136 of the inner case 130 . At this time, the external sensor 183 may be exposed to the outside through the outer top plate hole 127 and the cover top plate hole 117 . Therefore, the external air condition can be accurately measured through the external sensor 183 . In this embodiment, the external sensor 183 may constitute a part of the control unit 180, but otherwise, the external sensor 183 may be disposed to be spaced apart from the control unit 180.

As shown in FIG. 8 , an internal sensor 185 may be provided in the housing space S. The internal sensor 185 is for measuring the internal air condition of the housing space (S). The internal sensor 185 may measure the air or humidity inside the housing space (S). The internal sensor 185 may be disposed at a location far from the temperature controller 200 . That is, the internal sensor 185 may be disposed at a position spaced apart from the temperature controller 200 so that the cold air or warm air discharged from the temperature controller 200 does not directly affect the internal sensor 185. can In this embodiment, the internal sensor 185 is disposed at the upper corner of the housing space S corresponding to the opposite side of the duct guide 260.

The controller 180 may compare the temperature of the housing space S measured by the internal sensor 185 with the temperature measured by the external sensor 183 . In addition, when the difference between the external temperature and the temperature of the housing space S is greater than a reference value, the controller 180 may operate or stop the temperature control device 200 . For example, when the inside of the housing space (S) is colder or hotter than the outside, the thermostat 200 can be operated. Alternatively, the controller 180 may operate the temperature control device 200 based only on the external temperature.

The temperature controller 200 may be disposed in the housing module 100 . The temperature control device 200 may serve to cool or heat external air to supply cool air or warm air. To this end, the temperature control device 200 may suck in external air, cool or heat it, and then discharge it toward the housing space S and the rod assembly 400 .

Referring to FIG. 8 , the temperature controller 200 may be disposed between the inner side plate 133 of the inner case 130 and the outer side plate 123 of the outer case 120 . More precisely, the temperature controller 200 may be disposed in the installation space 165a of the heat insulating member 160 . At this time, the first control fan (F1) of the temperature controller 200 may be disposed to face the outside of the case cover 110, and the second control fan (F2) may be disposed to face the housing space (S).

The air discharged through the second control fan (F2) of the temperature control device (200) may first flow into the duct guide (260). Some of the air introduced into the duct guide 260 may flow into the housing space S through the first guide outlet 263a of the duct guide 260 (in the direction of arrow 1 in FIG. 8), and the rest Air may be introduced in the direction of the rod assembly 400 through the second guide outlet 263b (direction of arrow 2 in FIG. 8). At this time, the air introduced into the housing space S is also introduced into the communication cap DC ) through the cap hole (DC') of the duct fan 300 (in the direction of the arrow 1' in FIG. 8). Air introduced in this direction can be sucked into the duct fan 300 (in the direction of arrow 2' in FIG. 8).

In addition, air may be discharged downward (in the direction of arrow 3) of the rod assembly 400 by the duct fan 300 . At this time, some of the air discharged downward of the rod assembly 400 may be discharged to the outside of the rod assembly 400 through the rod discharge holes 550, 650, and 750 formed in the rod assembly 400. (arrow 3) ' direction) Accordingly, cold air or warm air may be supplied toward the seat portions 918 and 920 disposed outside the rod discharge holes 550 , 650 , and 750 . In particular, in this embodiment, since the rod discharge holes 550 , 650 , and 750 are open to the top or bottom of the seat parts 918 and 920 , cold air or warmth can be supplied to companion animals sitting on the seat parts 918 and 920 .

Looking at the structure of the temperature controller 200 with reference to FIG. 8 , the device housing 211 may be provided in the temperature controller 200 . The device housing 211 constitutes an exterior of the temperature control device 200 and may serve to fix each part. Temperature control fans F1 and F2 may be installed inside the device housing 211 . A surface of the device housing 211 may come into close contact with an inner surface of the installation space 165a. Reference numeral 210 denotes a housing cover, and the housing cover 210 may be fixed to the outer case 120 . For reference, in this embodiment, the temperature control fans F1 and F2 may include the first control fan F1 and the second control fan F2.

A recovery unit 212 may be formed in the device housing 211 . The collecting part 212 serves as a passage through which the air inside the housing space S can be introduced into the device housing 211 again. The recovery part 212 may be formed through a front surface of the device housing 211 facing the inner case 130 .

A mounting plate 213 may be provided inside the device housing 211 . The mounting plate 213 may have a substantially plate-like structure, and an edge portion thereof may be connected to the device housing 211 . The mounting plate 213 may serve to support components mounted on the device housing 211 .

A heat sink 214 and a cold sink 218 may be provided on the mounting plate 213 . Although not shown, a thermoelectric element may be disposed between the heat sink 214 and the cold sink 218 . The heat generated from the thermoelectric element heats the heat sink 214, and the heat of the heat sink 214 is transferred outwardly to the rear (see arrow 4 in FIG. 8) through the first control fan F1. may be discharged. In addition, the cold air of the cold sink 218 cooled by the thermoelectric element may be discharged forward toward the duct guide 260 (see arrows 1 and 2 in FIG. 8 ).

The thermoelectric element constituting the temperature controller 200, the heat sink 214, and the cold sink 218 may be disposed inside the installation space 165a, which is an insulating space. Accordingly, the thermoelectric element, the heat sink 214, and the cold sink 218 may be insulated from the peripheral portion, and cold air from the thermoelectric element may be concentrated toward the front duct guide 260.

The thermoelectric element constituting the temperature control device 200 has a shape like a flat plate having front and rear surfaces, and the front surface may be a heat absorbing surface and the rear surface may be a heating surface. DC power supplied to the thermoelectric element causes a Peltier effect, and accordingly, heat from the heat absorbing surface of the thermoelectric element is moved toward the heating surface. Therefore, the front surface of the thermoelectric element becomes a cold surface, and the rear surface becomes a heat generating part. That is, it can be said that the heat inside the housing space (S) is released to the outside of the outer case (120).

In this case, a heat sink 214 may be coupled to the heating surface, and a cold sink 218 may be coupled to the heat absorbing surface. Therefore, when the thermoelectric element of the thermostat 200 operates, the heat absorbing surface of the thermoelectric element absorbs heat from the housing space S through the cold sink 218 to cool the housing space S, and the heating surface Heat may be discharged to the outside through the heat sink 214 . At this time, the second control fan (F2) may be a cooling fan. The first control fan F1 blows cooling air to the heat transfer fins of the heat sink 214 to increase heat dissipation of the heat transfer fins. Reference numeral 214a denotes a heat pipe inserted into the heat transfer fin.

Conversely, the front surface of the thermoelectric element may be a heating surface and the rear surface may be a heat absorbing surface. In this case, heat may be generated on the front surface of the thermoelectric element, and a cold surface may be generated on the rear surface of the thermoelectric element. Accordingly, the temperature control device 200 may provide warmth to the inside of the housing space (S). Although not shown, power supplied to the thermoelectric element may be applied to the thermoelectric element through a cable provided in the thermoelectric element.

A duct guide 260 may be connected to the temperature controller 200 . The duct guide 260 may be disposed between the temperature controller 200 and the duct fan 300 . In this embodiment, a part of the duct guide 260 is surrounded by the heat insulating member 160, and the remaining part protrudes into the housing space (S). Alternatively, the entirety of the duct guide 260 may be disposed inside the heat insulating member 160 or may protrude into the housing space S.

Referring to FIGS. 10 and 11 , the duct guide 260 may have a substantially hexahedral shape. A guide passage 263, which is an empty space, may be formed inside the duct guide 260. The guide passage 263 may guide a discharge direction of cold air or warm air discharged through an air outlet (not shown) of the temperature controller 200 . Reference numeral 261 denotes a guide flange surrounding the air outlet of the temperature controller 200 .

A guide inlet 262 connected to an air outlet of the temperature controller 200 may be formed on one side of the duct guide 260 . The guide inlet 262 may be viewed as an inlet of the guide flange 261 . The guide inlet 262 may be connected to a first guide outlet 263a and a second guide outlet 263b.

A guide passage 263 may be formed in the duct guide 260 , and the guide passage 263 may include the first guide outlet 263a and the second guide outlet 263b. Among them, the first guide outlet 263a may be opened in the direction of the housing space S, and the second guide outlet 263b may be opened in the direction of the upper end of the duct fan 300. Accordingly, some of the air discharged from the temperature controller 200 may be delivered to the housing space S through the duct guide 260, and the remaining part may be supplied to the duct fan 300. This appearance is shown in FIG. 8 .

As shown in FIG. 8, some of the air introduced into the duct guide 260 may flow into the housing space S through the first guide outlet 263a of the duct guide 260 (see FIG. 8). direction of arrow 1), the remaining air may flow in the direction of the rod assembly 400 through the second guide outlet 263b (direction of arrow 2 in FIG. 8). Although not shown, the first guide outlet 263a ) or the size of the open area of the second guide outlet 263b may be adjusted through a separate device. When the open area of the first guide outlet 263a or the second guide outlet 263b is adjusted, the amount of discharged air is changed, and as a result, the temperature of the tower can be controlled more precisely.

Next, the duct fan 300 will be reviewed. The duct fan 300 may be disposed above the rod assembly 400 . The duct fan 300 may serve to suck air delivered from the housing space S and the duct guide 260 and discharge it to the lower part of the rod assembly 400 . The duct fan 300 may include a fan motor 321 (see FIG. 16 ), and a rotational force of the fan motor 321 may be used to induce air flow. The fan motor 321 of the duct fan 300 may be a brushed motor or a brushless motor.

In this embodiment, the duct fan 300 may be fixed inside the connection flange 169 of the heat insulating member 160 by a fan housing 330 to be described below. More precisely, the duct fan 300 is disposed on the upper end of the rod assembly 400 and can be disposed in an inner space surrounded by the connection flange 169 of the heat insulating member 160 at the same time.

Also, the duct fan 300 may be disposed in a direction orthogonal to the temperature control fans F1 and F2. That is, the second control fan (F2) among the temperature control fans (F1, F2) intensively discharges air toward the duct guide 260, and the duct fan 300 discharges some of it downward, that is, The rod assembly 400 may be guided in the direction of the flow path inside the rod assembly 400 .

As shown in FIG. 18 , in this embodiment, the duct fan 300 may include a fan assembly 310 and a fan housing 330 . The fan assembly 310 may include a fan motor 321 and an impeller 323 , and the fan housing 330 may fix the fan assembly 310 to the rod assembly 400 . The fan assembly 310 and the fan housing 330 may be assembled to the rod assembly 400 after being assembled to each other.

The impeller 323 of the fan assembly 310 may have a substantially circular skeleton. The impeller 323 is equipped with a plurality of blades, and can discharge after sucking in cold air or warm air by the temperature control device. The blades may be arranged radially around the hub 322 to press air downward. A hub 322 may be provided at the center of the impeller 323 . An empty space is provided inside the hub 322, and a fan motor 321 (see FIG. 16) may be disposed therein. Rotational force of the fan motor 321 may be transmitted to the impeller 323 to rotate the impeller 323 .

A control board 325 may be disposed under the impeller 323 . The control board 325 may further include an inverter, which is a power supply device capable of varying a frequency in order to operate the fan motor 321 at an arbitrary speed. A disk-shaped fan plate 327 supporting the control board 325 may be disposed under the control board 325 . Although not shown, a diffuser may be provided in the duct fan 300, and the diffuser may guide air introduced from the top downward, that is, toward the impeller 323.

A fan housing 330 may be coupled to the fan assembly 310 . The fan housing 330 may be coupled to the fan assembly 310 to surround the periphery of the fan assembly 310 . The fan housing 330 has a substantially cylindrical shape, and a coupling space 335, which is an empty space for coupling with the fan assembly 310, may be formed at the center. The fan housing 330 may allow air to be concentrated in the fan assembly 310 without leaking to the periphery of the fan assembly 310 . Referring to FIG. 16 , the fan housing 330 may fill the gap between the inner surface of the first rod 500 and the fan assembly 310 , and thus the introduced air flows downward only through the fan assembly 310 . can be ejected.

As shown in FIG. 18, the fan housing 330 may include two bodies having different diameters. A lower housing 331 may be provided under the fan housing 330 . In addition, an upper housing 333 having a smaller diameter than the lower housing 331 may be provided above the lower housing 331 . The control board 325 and the fan plate 327 may be disposed inside the lower housing 331 . The fan assembly 310 may be disposed inside the upper housing 333 .

Referring to FIG. 16 , it can be seen that the lower housing 331 constituting the fan housing 330 is disposed on top of the first rod 500 . In this embodiment, the lower housing 331 is seated on the mounting flange 517 of the first rod 500 . Accordingly, the entire fan housing 330 including the lower housing 331 may be disposed inside the connection flange 169 of the heat insulating member 160 . Alternatively, the fan housing 330 may be disposed inside the first rod 500 .

In this embodiment, the diameter of the fan assembly 310 is smaller than the diameters of the control board 325 and the fan plate 327, and the upper housing 333 corresponds to the diameter of the fan assembly 310. It may be made smaller than the lower housing 331 . Accordingly, the upper housing 333 may allow the air around the duct fan 300 to be concentrated in the fan assembly 310 without leaking out to the periphery of the fan assembly 310 .

A plate fastening part 329 may be provided on the fan plate 327 of the fan assembly 310 . Also, the fan housing 330 may include a housing fastening part 339 corresponding to the plate fastening part 329 . Although not shown, fasteners such as screws are coupled to the plate fastening part 329 and the housing fastening part 339 so that the fan plate 327 and the fan housing 330 can be coupled to each other.

Referring to FIGS. 8 and 16 , the duct fan 300 operates to suck air from the upper portion. As can be seen, the duct fan 300 not only sucks air through the duct guide 260, but also sucks air inside the housing space S. Also, the duct fan 300 may suck in air and simultaneously discharge air toward the inside of the first rod 500 . Therefore, the air cooled or heated by the temperature controller can move downward with more straightness.

17 shows the internal structure of the tower. Air discharged downward by the duct fan 300 may move along an air passage formed inside the duct assembly 400 . The air passage may be formed by continuously connecting the first passage space 511 , the second passage space 611 , and the third passage space 711 to each other.

The air discharged by the duct fan 300 may be transferred to the second passage space 611 after moving downward (in the direction of arrow ①) along the first passage space 511 . At this time, some air may be discharged outward (in the direction of arrow ① ') through the first rod discharge hole 550 . Since some of the plurality of first rod discharge holes 550 are opened toward the second seat assembly 900b, cold or warm air may be provided to companion animals staying in the second seat assembly 900b.

The air delivered to the second passage space 611 may move downward (direction of arrow ②). Also, some of the air is discharged through the second rod discharge hole 650 of the second rod 600 (see FIG. 2 ) to provide cool or warm air to the companion animal staying in the fourth seat assembly 900d.

Subsequently, the air delivered to the third passage space 711 may move downward (in the direction of the arrow ③). The air moved downward can be discharged to the outside of the tower (in the direction of arrow ④) through the passage outlet 715. A companion animal staying below the passage outlet 715 may receive cold air or warm air discharged through the passage outlet 715 . At the same time, some air is discharged outward (in the direction of arrow ③') through the third rod discharge hole 750 of the third rod 700, and the companion animal staying in the fifth seat assembly 900e receives cold air or Can provide warmth.

On the other hand, looking at Figure 20, it can be seen that the height of the tower is adjusted. As can be seen from this, while the length of the rod assembly 400 constituting the tower in this embodiment is varied, the height of the entire tower can be varied. The rod assembly 400 is composed of a plurality of rods 500, 600, and 700, and the length of the rod assembly 400 may change as the rods 500, 600, and 700 overlap or spread each other. 20(a) shows the longest state of the rod assembly 400, and FIG. 20(c) shows the shortest state of the rod assembly 400.

More precisely, the rod assembly 400 may include a first rod 500, a second rod 600 and a third rod 700. The first rod 500, the second rod 600, and the third rod 700 may have different diameters and be connected in an overlapping manner. In this embodiment, the second rod 600 is connected to the lower part of the first rod 500, and the third rod 700 is connected to the lower part of the second rod 600. 20(b) shows a state in which the third rod 700 is maximally overlapped with the second rod 600, and FIG. 20(c) shows the second rod 600 overlapping the first rod 500 is maximally overlapped.

In this embodiment, the cross section of the first rod 500, the cross section of the second rod 600, and the cross section of the third rod 700 are each circular. In addition, the cross section of the first rod 500, the cross section of the second rod 600, and the cross section of the third rod 700 may have different diameters. For example, the diameter of the cross section of the first rod 500 may be the largest and the diameter of the cross section of the third rod 700 may be the smallest. Accordingly, the first rod 500, the second rod 600, and the third rod 700 may overlap each other.

The rod assembly 400 may be automatically or manually variable in length. For example, although not shown, an elevating device may be provided inside the rod assembly 400, and a motor of the elevating device may elevate the rods 500, 600, and 700. At this time, the elevating device may be composed of a gear and a rail, or may be composed of a rope and a winder.

Alternatively, the user may manually adjust the length of the rod assembly 400. For example, the user pushes the third rod 700 toward the inside of the second rod 600 to increase a section where the third rod 700 and the second rod 600 overlap each other, and accordingly, the rod The length of the assembly 400 may be reduced. Although not shown, height adjustment holes are formed in each of the third rod 700 and the second rod 600, and when an adjustment pin is inserted into the height adjustment hole, the third rod 700 and the second rod 700 The rods 600 can be fixed to each other without unfolding again. Alternatively, since the third rod 700 and the second rod 600 have a screw fastening structure, the length may be adjusted by a screw fastening method. And in the same way, the first rod 500 and the second rod 600 may overlap or spread each other.

At this time, since the seat assemblies 900a to 900e and the scratchers 950a and 950b are fixed to the rod assembly 400, when the rods 500, 600 and 700 are moved up and down, the seat assemblies 900a to 900e And the scratchers 950a and 950b may also be lifted together. Therefore, the user can simultaneously adjust the heights of the rod assembly 400, the seat assembly 900, and the scratchers 950a and 950b.

21 and 22 show the structure of the rod assembly 400. As can be seen from this, the rod assembly 400 may be a kind of tubular structure extending long in one direction. The rod assembly 400 may include a plurality of rods 500, 600, and 700. The plurality of rods 500, 600, and 700 may be connected to each other to form a continuous air flow path therein. In this embodiment, the rod assembly 400 may include a total of three rods 500, 600, and 700. Alternatively, the rod assembly 400 may include two or fewer rods or four or more rods.

The three rods 500, 600, and 700 may have a variable overall length while overlapping or spreading each other. That is, the three rods 500, 600, and 700 may constitute a kind of rod antenna structure. Hereinafter, each of the rods 500, 600, and 700 will be examined.

First, the first rod 500 is shown in FIGS. 23 and 24 . Looking at the first rod 500, the first rod 500 may include a substantially cylindrical first rod body 510. A first seat lifting device 800a to be described below may be disposed in the first passage space 511 provided inside the first rod body 510 . An upper end of the first rod 500 may be fixed to the housing module 100 and a lower end of the first rod 500 may overlap the second rod 600 . That is, since the lower end of the first rod 500 is not fixed, the first rod 500 may be viewed as a cantilever structure as a whole.

At this time, the first passage space 511 may be connected to the second passage space 611 and the third passage space 711 to be described later to form one air passage. Here, the air passage can be viewed as an empty space defined between the inside of the rod assembly 400 and the lower portion of the housing module 100 .

Referring to FIG. 24 , an inner case 515 may be provided in the first rod 500 . In the inner case 515, a first seat lifting device 800a to be described below is disposed. The inner case 515 may have a substantially hexahedral shape, and one side may be open. A mounting space 516 may be provided inside the inner case 515, and the first seat lifting device 800a may be disposed in the mounting space 516. In this embodiment, the upper and lower portions of the inner case 515 are blocked, respectively, but otherwise, the upper or lower portion of the inner case 515 may have an open structure.

A first elevation slot 518 may be formed in the inner case 515 . The first elevating slot 518 may be formed along the longitudinal direction of the first rod 500 . The first elevating slot 518 may be made by penetrating the first rod 500 . The first lift slot 518 may correspond to a housing slot 818 (see FIG. 32) of the first seat lift device 800a to be described below. The elevating bridge 837 of the first seat elevating device 800a passes through the housing slot 818 and the first seat elevating device 800a, respectively, and the step station is at one end of the elevating bridge 837. The mounting bracket 911 of 918 may be connected.

A mounting flange 517 may be provided at an upper end of the first rod 500 . Referring to FIG. 16 , the mounting flange 517 may be a portion in contact with the connection flange 169 of the heat insulating member 160 . The mounting flange 517 may have a kind of plate-like structure so as to widen the width of the upper end of the first rod 500 . The mounting flange 517 may be assembled with the connection flange 169 by a separate fastener (not shown) in a state where the mounting flange 517 comes into contact with the connection flange 169 .

Referring back to FIG. 24 , a first sealing end 530 may protrude from the lower end of the first rod 500 . The first sealing end 530 may protrude in a direction narrowing the diameter of the first rod 500 . The first sealing end 530 may have a substantially ring shape. The first sealing end 530 may prevent the separation of the first sealing member S1, which will be described below, and form a sealing space.

Referring to FIG. 15 , the first sealing end 530 may protrude toward the surface of the second rod 600 . Also, a second upper sealing end 630 may protrude from the second rod 600 toward the surface of the first rod 500 . Accordingly, a predetermined empty space is formed between the first sealing end 530, the second upper sealing end 630, the inner surface of the first rod 500 and the outer surface of the second rod 600. can Also, the first sealing member S1 may be disposed in this empty space. The first sealing member S1 may prevent cold or warm air from leaking to the outside of the rod assembly 400 .

In this embodiment, the first sealing member (S1) has a ring shape. The first sealing member S1 may be made of an elastic material. The first sealing member S1 is compressed between the first rod 500 and the second rod 600 to improve sealing performance. The first sealing member S1 may be fixed to either the first sealing end 530 of the first rod 500 or the second upper sealing end 630 of the second rod 600 . Alternatively, the first sealing member S1 may not be fixed to the first rod 500 or the second rod 600.

As such, the first sealing member S1 may be disposed at an overlapping portion where the rods 500 and 600 interfere with each other. Accordingly, the first sealing member (S1) can be naturally compressed between the first rod 500 and the second rod 600. When the first sealing member S1 is compressed, sealing performance between the first rod 500 and the second rod 600 may be increased.

Meanwhile, a first rod discharge hole 550 may be opened in the first rod 500 . The first rod discharge hole 550 may be formed through the first rod 500 . The first rod discharge hole 550 may connect the first passage space 511 of the first rod 500 to the outside of the rod assembly 400 . Cold and warm air inside the first passage space 511 may be discharged to the outside through the first rod discharge hole 550 . In addition, companion animals staying outside the first rod discharge hole 550 may be supplied with cold air or warm air discharged through the first rod discharge hole 550 . A plurality of first rod discharge holes 550 may be formed in the first rod 500 . In this embodiment, three first rod discharge holes (550, see FIG. 23) are formed in the first rod 500 with different heights. Unlike this, two or less or four or more first rod discharge holes ( 550) may be formed on the first rod 500.

When cold air is discharged through the first rod discharge hole 550, the surface temperature of the inner surface of the first rod 500 around the first rod discharge hole 550 is higher than that of the outer surface of the first rod 500. may be low. In this case, dew condensation may occur on the inner surface of the first rod 500 . If this dew condensation becomes severe, water may flow along the inner surface of the first rod 500 .

In this embodiment, a rod heater 570 may be added to prevent such dew condensation. The rod heater 570 may heat the periphery of the first rod discharge hole 550 to reduce a temperature difference between an inner surface and an outer surface of the first rod 500 . To this end, the rod heater 570 may be disposed on an inner surface of the first rod 500 corresponding to the periphery of the first rod discharge hole 550 .

Referring to FIG. 25 , the rod heater 570 is disposed on the inner surface of the first rod 500 to increase the temperature of the inner surface of the first rod 500 . The rod heater 570 may increase the temperature of the inner surface of the first rod 500 to reduce a temperature difference between the inner surface and the outer surface of the first rod 500 . In particular, since dew condensation easily occurs around the first rod discharge hole 550 , the rod heater 570 may be disposed around the first rod discharge hole 550 . Condensation may occur when external warm air comes into contact with the periphery of the first rod discharge hole 550 through which cold air is discharged. In this embodiment, condensation is prevented by reducing the temperature difference with the rod heater 570 It can be done.

As shown in FIG. 25 , the rod heater 570 may be disposed on an inner circumferential surface of the first rod 500 . More precisely, the rod heater 570 may be fixed to the inner surface of the inner case 515 provided on the first rod 500 . A first lift slot 518 connected to the outside is formed in the inner case 515, and condensation may occur around the first lift slot 518 due to a temperature difference between the inside and the outside. In this embodiment, the rod The heater 570 raises the ambient temperature of the first elevation slot 518 to prevent dew condensation. In FIG. 25, an arrow indicates a direction in which heat from the rod heater 570 is transferred to the surroundings.

FIG. 26 shows a state in which the rod heater 570 is disposed in a form different from that of FIG. 25 . The rod heater 570 may be disposed on the inner surface of the first rod 500 at a position outside the inner case 515, not on the inner surface of the inner case 515. Even in this case, since the rod heater 570 can increase the ambient temperature of the first rod discharge hole 550 and the first elevating slot 518, it is possible to prevent condensation. 26 shows a structure in which the rod heater 570 extends to a position adjacent to one side of the first rod discharge hole 550 .

Meanwhile, the rod heater 570 may be disposed on the surface of the first seat lifting device 800a facing the inner surface of the first rod 500, not on the inner surface of the first rod 500. As shown in FIG. 32, since the elevating housing 810 of the first seat elevating device 800a faces the inner surface of the first rod 500, the rod heater 570 is attached to the elevating housing 810. may be placed.

Also, the rod heater 570 may be provided not only in the first rod 500 but also in the second rod 600 and the third rod 700 . However, since condensation is most likely to occur in the first rod 500 closest to the temperature controller 200, it is preferable that the rod heater 570 is disposed on the first rod 500.

27 shows the rod heater 570. As can be seen from this, in this embodiment, the rod heater 570 may be composed of a thin plate-shaped film type heater. The rod heater 570 may include a film material that can be easily bent. More precisely, the rod heater 570 may include a heat insulating film 571 and a hot wire 575 embedded in the heat insulating film 571 . Here, the insulation film 571 may be formed of a polyethylene terephthalate (PET) material. The insulating film 571 forms an outer surface of the rod heater 570 and may include a first film and a second film located on opposite sides of each other.

The heating wire 575 may be a heating element that generates heat by receiving external power. The hot wire 575 may include a silver (Ag) material. The heat wire 575 may be provided on the heat insulating film 571 in a form bent multiple times. The distal end 576 of the hot wire 575 may be a part receiving external power, and a separate terminal (not shown) may be coupled to the distal end 576.

The rod heater 570 may be directly fixed to the inner surface of the first rod 500 or to the surface of the elevating housing 810 . Alternatively, the rod heater 570 may be configured in such a way that the heat insulation film 571 is omitted and the hot wire 575 is directly embedded or fixed to the first rod 500 .

At this time, a rod temperature sensor (not shown) may be disposed around the first rod discharge hole 550 . The rod temperature sensor may measure the ambient temperature of the first rod discharge hole 550 . When the difference between the ambient temperature of the first rod discharge hole 550 measured by the rod temperature sensor and the external temperature measured by the external sensor 183 is greater than a predetermined standard, the first rod discharge hole 550 Condensation is likely to occur in the vicinity. Accordingly, the controller 180 may operate the rod heater 570 to reduce the difference between the ambient temperature of the first rod discharge hole 550 and the external temperature, thereby preventing condensation.

Looking at the second rod 600 with reference to FIGS. 28 and 29, the second rod 600 may include a substantially cylindrical second rod body 610 similar to the first rod 500. . The second passage space 611 provided inside the second rod body 610 may be connected to the first passage space 511 of the first rod 500 . Also, a second seat lifting device 800b may be disposed in the second passage space 611 .

Mounting guides 615a and 615b may be provided on the second rod 600 . The mounting guides 615a and 615b allow the second seat elevating device 800b to be mounted inside the second rod 600 . The mounting guides 615a and 615b may be provided inside the second passage space 611 . In this embodiment, the mounting guides 615a and 615b may include a first mounting guide 615a and a second mounting guide 615b. The first mounting guide 615a and the second mounting guide 615b may have a substantially plate-shaped structure spaced apart from each other. Both sides of the elevating housing 810 constituting the second seat elevating device 800b may be in close contact with the first mounting guide 615a and the second mounting guide 615b, respectively. Either of the first mounting guide 615a and the second mounting guide 615b may be omitted.

A second lift slot 618 may be formed in the second rod 600 . The second elevating slot 618 may be formed along the longitudinal direction of the second rod 600 . The second elevating slot 618 may be made by penetrating the second rod 600 . The second lift slot 618 may correspond to a housing slot (not shown) of the second seat lift device 800b. The elevating bridge (837, see FIG. 17) of the second seat elevating device 800b passes through the housing slot and the second rod 600, respectively, and the step station ( The mounting bracket 911 of 918 may be connected.

A second upper sealing end 630 may be provided at an upper end of the second rod 600 . The second upper sealing end 630 may protrude from the upper edge of the second rod 600 in a direction of widening the diameter of the second rod 600 . In this embodiment, the second upper sealing end 630 has a ring shape. The second upper sealing end 630 (i) is hooked on the first sealing end 530 of the first rod 500 so that the second rod 600 is completely separated from the first rod 500. (ii) the first sealing member (S1) can be fixed.

A second lower sealing end 640 may be provided at a lower end of the second rod 600 . The second lower sealing end 640 may protrude from the lower edge of the second rod 600 in a direction to narrow the diameter of the second rod 600 . In this embodiment, the second lower sealing end 640 has a ring shape. The second lower sealing end 640 (i) prevents the third rod 700 from being completely separated from the second rod 600 by hanging the third sealing end 730 of the third rod 700. (ii) the second sealing member (S2) can be fixed.

Referring to FIGS. 1 and 4 , a second rod discharge hole 650 may be formed in the second rod 600 . The second rod discharge hole 650 may be formed through the second rod 600 . The second rod discharge hole 650 may connect the second passage space 611 of the second rod 600 to the outside of the rod assembly 400 . Cold and warm air inside the second passage space 611 may be discharged to the outside through the second rod discharge hole 650 . In addition, companion animals staying outside the second rod discharge hole 650 may be supplied with cool air or warm air discharged through the second rod discharge hole 650 . A plurality of second rod discharge holes 650 may be formed in the second rod 600 .

Although not shown, a rod heater may be disposed on the second rod 600 as well. The rod heater is disposed on the inner surface of the second rod 600 to increase the temperature of the inner surface of the second rod 600 . The rod heater may be disposed on the inner surface of the second rod 600 or on the surface of the second seat lifting device 800b. Since the structure of the rod heater has been described above, a detailed description thereof will be omitted.

30 and 31 show the third rod 700. The third rod 700 may have a cylindrical shape like the first rod 500 and the second rod 600 . A third passage space 711 may be formed inside the third rod body 710 constituting the third rod 700 . The third passage space 711 may be connected to the second passage space 611 and the first passage space 511 to form a continuous air passage.

A lower end of the third rod 700 may be opened. A passage outlet 715 may be formed at a lower end of the third rod 700 . The passage outlet 715 may be formed by opening a lower end of the third rod 700 downward. Cold air or warm air may be discharged through the passage outlet 715 . Thus, cold or warm air can be supplied to companion animals staying at the bottom of the tower.

Although not shown, a lower cover is provided at the lower end of the third rod 700, and the lower cover can selectively block the passage outlet 715. When the lower cover blocks the passage outlet 715, the air moving along the air passage is not discharged to the passage outlet 715, and the first rod discharge hole 550 and the second rod discharge hole 650 ) or may be discharged only through the third rod discharge hole 750 .

A rod flange 717 may be provided at a lower end of the third rod 700 . The rod flange 717 may have a structure in which a lower end of the third rod 700 protrudes upward. A flange channel 718 may be formed at a lower end of the third rod 700 by the rod flange 717 around the passage outlet 715 . The flange channel 718 may be a substantially ring-shaped empty space. Even if fluid flows along the inner wall of the air passage, it may accumulate in the flange channel 718 . A separate drip tray may be mounted on the flange channel 718, or an outlet opening the flange channel 718 to the outside may be formed.

A third sealing end 730 may be provided at an upper end of the third rod 700 . The third sealing end 730 may protrude from the upper edge of the third rod 700 in a direction of widening the diameter of the third rod 700 . In this embodiment, the third sealing end 730 has a ring shape. The third sealing end 730 (i) is hooked on the second lower sealing end 640 of the second rod 600 so that the third rod 700 is completely separated from the second rod 600 (ii) the second sealing member (S2) can be fixed. 15, the second sealing member S2 is disposed between the second lower sealing end 640 of the second rod 600 and the third sealing end 730 of the third rod 700. can see

The second sealing member S2 may have a ring shape like the first sealing member S1. The second sealing member S2 may be made of an elastic material. The second sealing member S2 is compressed between the second rod 600 and the third rod 700 to improve sealing performance. In this way, it is possible to prevent air from leaking into the gap between the second rod 600 and the third rod 700 . The second sealing member S2 may be fixed to either the second lower sealing end 640 of the second rod 600 or the third sealing end 730 of the third rod 700 . Alternatively, the second sealing member S2 may not be fixed to the second rod 600 or the third rod 700 .

A third rod discharge hole 750 may be opened in the third rod 700 . The third passage space 711 may be open to the outside through the third rod discharge hole 750 . Cold air or warm air from the air passage may be supplied to the seat portions 918 and 920 through the path formed by the third rod discharge hole 750 . The third rod discharge hole 750 may connect the third passage space 711 of the third rod 700 to the outside of the rod assembly 400 . Cold and warm air inside the third passage space 711 may be discharged to the outside through the third rod discharge hole 750 . In addition, companion animals staying outside the third rod discharge hole 750 can receive cold air or warm air discharged through the third rod discharge hole 750 .

Although not shown, a blocking cover may be provided in the first rod discharge hole 550, the second rod discharge hole 650, or the third rod discharge hole 750, and the blocking cover is the first rod discharge hole 550. Air may be prevented from being discharged to the outside by selectively blocking the rod discharge hole 550 , the second rod discharge hole 650 , or the third rod discharge hole 750 . For example, when the companion animal mainly stays only in the housing space (S), it blocks the first rod discharge hole 550, the second rod discharge hole 650, or the third rod discharge hole 750 to cool air. This is to prevent the heat from escaping to the outside.

The rod assembly 400 may be provided with seat elevating devices 800a and 800b. The seat elevating devices 800a and 800b may serve to automatically elevate the seat assembly 900 . The seat lifting devices 800a and 800b may be disposed inside the rod assembly 400 . Referring to FIG. 17, in this embodiment, the seat lifting devices 800a and 800b are arranged inside the first seat lifting device 800a disposed inside the first rod 500 and inside the second rod 600. and a second seat lifting device 800b disposed thereon.

The first seat lifting device 800a can lift the second seat assembly 900b, and the second seat lifting device 800b can lift the third seat assembly 900c. At this time, since the first scratcher 950a is connected to the second seat assembly 900b, the first scratcher 950a can also be moved up and down by the first seat lifting device 800a. Also, since the second scratcher 950b is connected to the third seat assembly 900c, the second scratcher 950b can also be moved up and down by the second seat lifting device 800b. For reference, since the first seat lifting device 800a and the second seat lifting device 800b have similar structures except for different heights, the following will be described based on the first seat lifting device 800a. do it with

32 and 33 show how the second seat assembly 900b is lifted by the first seat lifting device 800a. 32 shows the second seat assembly 900b in a lowered state, and FIG. 33 shows the second seat assembly 900b in a raised state. As such, the first seat elevating device 800a may elevate the second seat assembly 900b in a vertical direction. In this process, the first scratcher 950a may also be lifted together.

Referring to FIG. 32 , the first seat lifting device 800a may be disposed in the first passage space 511 of the first rod 500. More precisely, the first seat elevating device 800a may be fixed inside the inner case 515 . An elevating housing 810 may be included in the first seat elevating device 800a. The elevating housing 810 is disposed inside the inner case 515, and a driving box 821 to be described below is disposed inside the elevating housing 810.

34 and 35 show the structure of the elevating housing 810. The elevating housing 810 may elongate in a vertical direction, that is, in an elevating direction of the second seat assembly 900b. An elevation space 811 may be formed inside the elevation housing 810 . The lift space 811 is open to one side, and the driving box 821 can be accommodated in the opened portion.

As shown in FIG. 35 , an elevation guide 812 may be provided in the elevation space 811 . The elevation guide 812 is erected vertically in the elevation space 811 . The elevating guide 812 may be combined with an elevating bar 830 to be described below to guide the elevating bar 830. More precisely, the elevating guide 812 is inserted into the elevating hole 831 (see FIG. 40) of the elevating bar 830, and the elevating bar 830 is connected to the elevating guide 812 and moves up and down. It can be lifted along the guide 812. Each of the elevation guide 812 and the elevation hole 831 may have a circular cross section.

An open hole 815 may be formed on a bottom surface of the elevation space 811 . The lift bar 830 may move through the open hole 815 . That is, the lower part of the lift bar 830 can protrude outward from the lift housing 810 through the open hole 815 . Alternatively, the elevating housing 810 may have a structure in which both upper and lower ends are open.

A communication slot 818 may be formed in the elevating housing 810 . The communication slot 818 may extend in a height direction of the elevating housing 810 (a vertical direction with reference to FIG. 34 ). The communication slot 818 is formed to penetrate the elevating housing 810, so that the elevating bridge 837 of the elevating bar 830, which will be described later, can protrude through the communication slot 818. Since the communication slot 818 is connected to the first elevation slot 518 of the first rod 500, the elevation bridge 837 continuously connects the communication slot 818 and the first elevation slot 518. It can pass through and protrude outward of the first rod 500. 17 shows a state in which the elevating bridge 837 passes through the communication slot 818 and the first elevating slot 518 .

Referring to FIG. 35 again, a guide rail 819 may be provided on an inner wall of the elevating space 811 . The guide rail 819 may protrude from an inner wall of the elevation space 811 . The guide rail 819 may extend along the lifting direction of the lifting bar 830. In this embodiment, the guide rail 819 extends parallel to the lifting guide 812. A guide rib 839 (see FIG. 40 ) of the lifting bar 830 may be inserted into the guide channel 819a formed in the guide rail 819 . Therefore, the lifting bar 830 can be guided by the guide rail 819 as well as the lifting guide 812, and can be stably moved along a certain direction. The guide rail 819 may be integrally formed with the inner wall of the elevating housing 810 or may be a separate object from the elevating housing 810 . Alternatively, the guide rail 819 may be formed on the inner surfaces of the rods 500, 600, and 700. Of course, the guide rail 819 or the guide channel 819a may be formed on the lifting bar 830, and the guide rib 839 may be formed on the inner surface of the rods 500, 600, or 700 or on the lifting housing 810.

An elevation driver 820 may be disposed in the elevation housing 810 . The lifting driver 820 is for lifting the lifting bar 830 . Since the second seat assembly 900b and the first scratcher 950a are connected to the lifting bar 830, the second seat assembly 900b and the first scratcher 950a are controlled by the lifting driver 820. ) can be seen as being elevated. For such an elevation operation, an elevation motor M1 and a gear assembly may be incorporated in the elevation driving unit 820 .

The lift driver 820 may include a drive box 821 . The driving box 821 may form a skeleton of the lifting driving unit 820 . The driving box 821 may have a substantially hexahedral shape. An elevating motor M1 and a gear assembly may be disposed inside the driving box 821 . The driving box 821 may be disposed in a fixed state inside the elevating housing 810 . In this embodiment, the driving box 821 is disposed below the elevation space 811, but may be disposed above the elevation space 811, unlike this.

36 and 37 represented as cross-sectional views, it can be seen that the lift motor M1 and gears are disposed inside the driving box 821. The gears may linearly move the lifting bar 830 while interlocking with the lifting motor M1. In this embodiment, the gears consist of a total of three gears. Among them, a main gear 826 to be described below may move the lifting bar 830 by engaging with the lifting bar 830 .

Referring to FIGS. 38 and 39 , it can be seen that the driving box 821 is disposed in close contact with the lifting bar 830 . The driving box 821 is driven in a fixed state, and the lifting bar 830 may move relative to the driving box 821 in a vertical direction. Also, the second seat assembly 900b connected to the lifting bar 830 and the lifting bridge 837 may be moved together with the lifting bar 830 .

41 and 42 show the inside of the drive box 821. For reference, in FIG. 41, the second box body 821b constituting the driving box 821 is omitted, and only the first box body 821a is shown. In this embodiment, the drive box 821 is composed of a first box body 821a and a second box body 821b. The first box body 821a and the second box body 821b are coupled to each other to fix the gears.

Looking at the structure of the drive box 821 in detail with reference to FIGS. 43 to 45, the drive box 821 may be composed of a first box body 821a and a second box body 821b. The first box body 821a and the second box body 821b are coupled to each other so that an empty space therein may form a driving space 822 (see FIG. 42). The first box body 821a may form part of the top and side surfaces of the driving box 821 and part of the front surface. Here, the front is based on FIG. 38 . And, the second box body 821b may constitute a bottom, a rear surface, a part of a side surface, and a part of the front surface of the drive box 821 .

Referring to FIG. 43 , the driving box 821 may have a structure bent in an approximate 'L' shape when viewed from above. In addition, the lifting bar 830 may be in close contact with the inside of the bent portion of the drive box 821 . At this time, a part of the second main gear teeth 826b constituting the main gear 826 may protrude outward through the gear hole GH of the driving box 821 and engage with the lifting bar 830. there is.

44 shows the first box body 821a. The gear hole GH is opened in the first box body 821a, and a part of the second main gear tooth 826b may protrude through the gear hole GH. Since the periphery of the gear hole GH is shielded, the driven gear 824 and the reduction gear 825 to be described later may not be exposed to the outside of the driving box 821 .

A gear fence GF may be provided in the first box body 821a. The gear fence GF may be for mounting the driven gear 824 and the reduction gear 825 . The gear fence GF has a substantially plate shape, and may be supported on at least two surfaces on an inner surface of the first box body 821a. A first driven gear groove 822a1 and a first reduction gear groove 822a2 may be formed in the gear fence GF. One end of the driven gear 824 may be rotatably inserted into the first driven gear groove 822a1, and one end of the reduction gear 825 may also be rotatably inserted into the first reduction gear groove 822a2. It can be.

45 shows the second box body 821b. The second box body 821b may be combined with the first box body 821a to define the drive space 822 therein. The second box body 821b can seal the drive space 822 to prevent foreign substances from entering the drive space 822 . In addition, the second box body 821b may also serve to fix the elevating motor M1 and gears.

A motor housing (MH) may be provided in the second box body (821b). The motor housing (MH) has a substantially cylindrical shape, and an elevation motor (M1) may be disposed therein. For reference, FIG. 40 shows a state in which the lifting motor M1 is housed in the motor housing MH. Along with the motor housing (MH), a second driven gear groove (822b1), a second reduction gear groove (822b2) and a pair of main gear grooves (822a3, 822b3) to which gears are fixed to the second box body (821b). ) can be formed.

At this time, the other end of the driven gear 824 may be rotatably inserted into the second driven gear groove 822b1, and the other end of the reduction gear 825 may also be inserted into the second reduction gear groove 822b2. It can be inserted rotatably. 42 shows a state in which both ends of the driven gear 824 are inserted into the first driven gear groove 822a1 and the second driven gear groove 822b1, respectively, and both ends of the reduction gear 825 are respectively inserted into the first reduction gear groove 822a1 and the second driven gear groove 822b1. A state fitted into the gear groove 822a2 and the second reduction gear groove 822b2 is shown.

The pair of main gear grooves 822a3 and 822b3 may face each other. In this embodiment, among the pair of main gear grooves 822a3 and 822b3, the first main gear groove 822a3 is formed on the inside of the structure protruding outward, and the second main gear groove 822b3 is the first main gear groove 822b3. It may be formed inside the structure protruding toward the gear groove (822a3). One end of the main gear 826 may be first fitted into the second main gear groove 822b3, and the other end of the main gear 826 may be fitted into the first main gear groove 822a3. In this process, the main gear 826 may be elastically deformed to some extent. 42 shows a state in which both ends of the main gear 826 are fitted into the first main gear groove 822a3 and the second main gear groove 822b3, respectively.

41 and 42 show the lift motor M1 and gears disposed inside the drive box 821. For reference, FIG. 41 is shown with the second box body 821b omitted. As can be seen, a motor gear 823 may be provided in the lifting motor M1. The motor gear 823 may be rotated together with the rotating shaft of the elevating motor M1.

A driven gear 824 may be engaged with the motor gear 823 . The motor gear 823 and the driven gear 824 may be composed of a worm and a worm gear. Accordingly, the rotational axis of the driven gear 824 may be orthogonal to the rotational axis of the motor. As such, since the worm and worm gear structure is applied to the present embodiment, the motor gear 823 does not rotate even when the load of the companion animal is applied to the seat portions 918 and 920. That is, when the lift drive unit 820 does not operate, a phenomenon in which the seat units 918 and 920 are arbitrarily lowered while the lift motor M1 slips due to the load of the companion animal can be prevented. Accordingly, the stability of the lift driver 820 can be increased, and damage to the lift motor M1 can be prevented.

At this time, the driven gear 824 may include a first driven gear 824a meshing with the motor gear 823 and a second driven gear 824b rotating the reduction gear 825 . The first driven gear 824a may have a larger diameter than the second driven gear 824b. This is for deceleration and improvement of the driving force of the elevation driving unit 820, and the deceleration structure will be described again below.

The reduction gear 825 may be engaged with the driven gear 824 and rotated. The reduction gear 825 rotates in the opposite direction to the driven gear 824 . The reduction gear 825 may constitute a reduction gear unit together with the driven gear 824 . To this end, the reduction gear 825 may include a first reduction gear 825a and a second reduction gear 825b engaged with the second driven gear 824b. In this case, the first reduction gear tooth 825a may have a larger diameter than the second reduction gear tooth 825b. For reference, the driven gear 824 and the reduction gear 825 may be viewed as a first driven gear and a second driven gear, respectively, or as a first reduction gear and a second reduction gear.

The reduction gear 825 may rotate the main gear 826 . The main gear 826 may move the lifting bar 830 while rotating by the reduction gear 825 . The main gear 826 may include a first main gear tooth 826a meshing with the second reduction gear tooth 825b and a second main gear tooth 826b meshing with the lifting bar 830. . In this case, the first main gear tooth 826a may have a larger diameter than the second reduction gear tooth 825b. Therefore, (i) deceleration can be achieved between the second driven gear tooth 824b and the first reduction gear tooth 825a, and (ii) the second reduction gear tooth 825b and the first main gear tooth ( 826a) may also decelerate. With this deceleration, the main gear 826 can move the lifting bar 830 with a greater torque.

The lifting bar 830 may be operated by the lifting driver 820 . The lifting bar 830 may have a substantially long bar shape. The lifting bar 830 may be lifted by being engaged with the main gear 826 constituting the lifting driving unit 820 . In addition, the lifting bar 830 may be connected to the second sheet assembly 900b to lift the second sheet assembly 900b and the first scratcher 950a connected to the second sheet assembly 900b. .

Referring to FIGS. 38 and 39 , an elevation hole 831 may be formed in the elevation bar 830 . The lifting hole 831 may be formed inside the lifting bar 830 along the longitudinal direction of the lifting bar 830, that is, along the moving direction of the lifting bar 830. An upper end of the lift hole 831 may be opened to an upper part of the lift bar 830 . The elevation guide 812 may be inserted into the elevation hole 831 through an open entrance of the elevation hole 831 . Therefore, the lifting bar 830 can be moved along the lifting guide 812 . In FIG. 40 , a state in which the elevation guide 812 is inserted into the elevation hole 831 is represented in a cross-sectional view.

A lift gear 835 may be provided on the surface of the lift bar 830 . The lifting gear tooth 835 meshes with the second main gear tooth 826b of the main gear 826 . The lifting bar 830 and the main gear 826 may be a kind of rack and pinion. That is, the rotational motion of the main gear 826, which is a pinion, can be converted into a linear motion of the lifting bar 830, which is a rack.

An elevating bridge 837 may be provided on the elevating bar 830 . The elevating bridge 837 may protrude from the elevating bar 830 in a direction orthogonal to the elevating direction of the elevating bar 830 (a vertical direction with reference to FIG. 38 ). The elevating bridge 837 may pass through the communication slot 818 of the elevating housing 810 and the first elevating slot 518 of the first rod 500, respectively. The elevating bridge 837 may protrude outward from the first rod 500 by successively passing through the communication slot 818 and the first elevating slot 518 . Referring to FIG. 17 , a state in which the elevating bridge 837 passes through the communication slot 818 and the first elevating slot 518 is shown.

A mounting bracket 911 of the second seat assembly 900b may be connected to one end of the elevating bridge 837 . Referring to FIG. 32 , the elevating bridge 837 passes through the communication slot 818 and the first elevating slot 518 and is connected to the mounting bracket 911 of the second seat assembly 900b. When the lift bar 830 moves, the lift bridge 837 moves along the communication slot 818 and the first lift slot 518 .

Referring to FIG. 39 , a guide rib 839 may protrude from the lift bar 830 . The guide rib 839 is inserted into the guide channel 819a of the guide rail 819, and the moving direction of the lift bar 830 can be guided by the guide rail 819. For reference, FIG. 40 shows a state in which the guide rib 839 is inserted into the guide channel 819a as a cross-sectional view.

The guide rib 839 may extend in a longitudinal direction of the lifting bar 830, that is, in a lifting direction of the lifting bar 830. Through this, the lifting direction of the lifting bar 830 may be guided. Conversely, a long groove may be formed in the lifting bar 830, and a guide rib 839 inserted into the long groove may protrude from the lifting housing 810.

Referring to FIG. 41 , a process of driving the lift driver 820 will be described. First, when the elevating motor M1 is rotated, the motor gear 823 of the elevating motor M1 may rotate in a first direction (direction of arrow ①). At the same time, the driven gear 824 meshed with the motor gear 823 may be rotated in the opposite direction (arrow ② direction). Subsequently, the reduction gear 825 meshed with the driven gear 824 may be rotated in a direction opposite to the rotational direction of the driven gear 824 (arrow ③ direction).

Also, the reduction gear 825 rotates the main gear 826 in the same direction as the rotation direction of the driven gear 824 (arrow ④ direction). The main gear 826 may move the lifting bar 830 in a downward direction (arrow ⑤ direction) while rotating. Conversely, when the motor gear 823 of the lifting motor M1 rotates in the second direction (opposite to the direction of arrow ①), the lifting bar 830 may rise.

At this time, (i) reduction may be made between the second driven gear 824b of the driven gear 824 and the first reduction gear 825a of the reduction gear 825, and (ii) the reduction Deceleration may also be achieved between the second reduction gear tooth 825b of the gear 825 and the first main gear tooth 826a of the main gear 826. With this deceleration, the main gear 826 can move the lifting bar 830 with a greater torque. Therefore, the lifting driver 820 can raise or lower the lifting bar 830 while overcoming the weight of the second seat assembly 900b and the first scratcher 950a connected to the lifting bar 830 .

Next, the seat assembly 900 will be looked at. The seat assembly 900 can be used for a companion animal to stay or step on and move. In this embodiment, the seat assembly 900 may include a seat station 920 that is comfortable for a companion animal to stay in, and a step station 918 that can be used by a companion animal to step on and move. Of course, the companion animal may use the seat station 920 as a staircase and stay at the step station 918.

The seat assembly 900 may be configured in plurality. Each of the plurality of seat assemblies 900 may include seat portions 918 and 920 . Each of the seat portions 918 and 920 may provide a seating surface for companion animals. The plurality of seat parts 918 and 920 form a kind of stairs, and companion animals may move by stepping on them in turn. In this embodiment, the seat assembly 900 is composed of a total of five (900a, 900b, 900c, 900d, 900e), and the seat portion (918, 920) is also composed of a total of five. Of course, the number of the seat assembly 900 and the seat portions 918 and 920 may be configured differently.

For reference, in this embodiment, the seat station 920 is included in the first seat assembly 900a and the fourth seat assembly 900d among the seat assemblies 900a to 900e, and the second seat assembly 900b , the step station 918 is included in the third seat assembly 900c and the fourth seat assembly 900d. The seat parts 918 and 920 provided in the seat assembly 900 may be configured differently from this. For example, each of the seat assemblies 900a to 900e may include a seat station 920 or, conversely, a step station 918.

Referring to FIG. 1 , among the seat assemblies, a first seat assembly 900a and a second seat assembly 900b may be fixed to the first rod 500 . Also, the third seat assembly 900c and the fourth seat assembly 900 may be fixed to the second rod 600 . Finally, the fifth seat assembly 900 may be fixed to the third rod 700. Accordingly, the third seat assembly 900c and the fourth seat assembly 900 can move up and down along the second rod 600, and the fifth seat assembly 900e can move up and down along the third rod 700. can

Meanwhile, the second seat assembly 900b is provided on the fixed first rod 500, but can be moved up and down independently of the first rod 500 by the first seat lifting device 800a described above. In addition, the third seat assembly 900c may be moved up and down together with the second rod 600, but may also be moved up and down independently of the second rod 600 by the second seat lifting device 800b.

As a result, in this embodiment, except for the first seat assembly 900a, the heights of the second to fifth seat assemblies 900b to 900e from the ground may be varied. Therefore, the tower of this embodiment can provide the heights of the seat portions 918 and 920 suitable for companion animals. Since the first seat assembly 900a is disposed right below the housing module 100 and can be used as a staircase when the companion animal moves to the housing space S, it is preferable to have a fixed height without being elevated. .

Looking at the first seat assembly 900a and the fourth seat assembly 900d with reference to FIG. 5 , a seat frame 910 is provided in the first seat assembly 900 and the fourth seat assembly 900d. can The seat frame 910 of the first seat assembly 900a may be fixed to the surface of the first rod 500, and the seat frame 910 of the fourth seat assembly 900b may be fixed to the surface of the second seat assembly 900b. It may be fixed to the surface of the rod 600.

The seat frame 910 may include a seat ring 917 on which the seat station 920 is seated. The seat ring 917 may extend from the seat frame 910 in a direction perpendicular to the lifting direction of the rod assembly 400 . The seat station 920 may be seated at the center of the seat ring 917 . In this embodiment, the seat station 920 is composed of a separate material from the seat frame 910 and can be detachably seated on the seat ring 917.

Meanwhile, the second seat assembly 900b, the third seat assembly 900c, and the fifth seat assembly 900e are each provided with a seat frame 910, and the step station 918 is provided in the seat frame 910. may be provided. The step station 918 may have a substantially plate-like structure. The step station 918 may be orthogonal to the seat frame 910 . That is, the step station 918 may extend from the seat frame 910 in a direction perpendicular to the lifting direction of the rod assembly 400 .

Mounting brackets 911 may be provided on the seat frames 910 of the second seat assembly 900b, the third seat assembly 900c, and the fifth seat assembly 900e. The mounting bracket 911 is for fixing the seat frame 910 to the surface of the rod assembly 400 . The mounting bracket 911 may have a substantially circular arc shape or a ring shape. In this embodiment, arc-shaped mounting brackets 911 are provided in the second seat assembly 900b and the third seat assembly 900c, and the ring-shaped mounting bracket 911 is provided in the fifth seat assembly 900e. ) is provided.

Although not shown, load sensors may be provided in the seat portions 918 and 920 . The load sensor may be pressed and turned ON when a companion animal sits on the seat portions 918 and 920 . That is, the load sensor is in an ON state at the moment the companion animal lands on the seat parts 918 and 920, and can transmit this to the control unit 180.

The control unit 180 may open or close the door 150 when a companion animal lands on the seat portions 918 and 920 . When the companion animal lands on the seat parts 918 and 920, since the companion animal can be regarded as being in a position close to the housing module 100, the control unit 180 opens the door 150 to allow the companion animal to enter the housing. It is to make it possible to enter the space (S). Conversely, when the companion animal staying in the housing space (S) lands on the seat parts (918, 920), the control unit 180 detects that the companion animal has left the housing space (S), and the control unit 180 opens the door 150 again. can be closed

In order to detect the movement of the companion animal, the load sensors may be respectively disposed on the first seat assembly 900a and the second seat assembly 900b. For example, if the load sensor of the first seat assembly 900a is turned on after the load sensor of the second seat assembly 900b among the load sensors is turned on, the companion animal enters the housing module 100. can be seen moving. Conversely, among the load sensors, if the load sensor of the second seat assembly 900b is turned on after the load sensor of the first seat assembly 900a is turned on, it prevents the companion animal from leaving the housing module 100. Able to know.

Meanwhile, although not shown, a buffer member such as a spring may be disposed on the seat portions 918 and 920 . When the companion animal sits on the seat portion 918 or 920, the buffer member is compressed and compressed by the weight of the companion animal, and may absorb an impact applied to the seat portion 918 or 920. For example, the seat parts 918 and 920 may be composed of a plurality of plates, and the buffer member may be disposed between the plurality of plates.

Next, the scratchers 950a and 950b will be examined. The scratchers 950a and 950b may provide companion animals with a scratching distance or increase frictional force when companion animals step on them. In this embodiment, the scratchers 950a and 950b may include a first scratcher 950a and a second scratcher 950b. The first scratcher 950a and the second scratcher 950b may be disposed at different heights. Accordingly, a companion animal may use the scratchers 950a and 950b of a preferred height, and several companion animals may each use the first scratcher 950a and the second scratcher 950b.

In this embodiment, the first scratcher 950a is connected to the second sheet assembly 900b and the second scratcher 950b is connected to the third sheet assembly 900c. Alternatively, the first scratcher 950a may be connected to the first sheet assembly 900a, or separate scratchers 950a and 950b may be connected to the first to fifth sheet assemblies 900a to 900e. there is. Since the first scratcher 950a and the second scratcher 950b have the same structure, the first scratcher 950a will be described below.

Referring to FIG. 46, the first scratcher 950a is shown in an unfolded state, and FIG. 47 shows the first scratcher 950a in a folded state. In this way, in this embodiment, the first scratcher 950a may be unfolded or folded through rotation. At this time, unfolding means that the first scratcher 950a is erected in the height direction of the rod assembly 400, as shown in FIG. 46, and folding means that the first scratcher 950a, as shown in FIG. 47, is the second seat assembly. This means a state in which it overlaps with (900b).

Referring to FIGS. 38 and 39 , the first scratcher 950a may have a substantially plate-like structure. One end of the first scratcher 950a may be connected to a connecting portion 918a extending from the seat frame 910 . The connecting portion 918a may extend downward from the bottom of the step station 918 . The first scratcher 950a may be rotatably connected to the connection part 918a. To this end, a hole may be formed in the connecting portion 918a so that the rotating shaft portion 985 of the first scratcher 950a is inserted.

A plurality of plate materials may be stacked on the first scratcher 950a. The plurality of plate materials may have similar shapes and areas, and may be viewed as one plate material when overlapped. One of the plurality of plate materials may be the base plate 960 and the other may be the out plate 970 . A link block 980 to be described below may be disposed on the base plate 960 . In addition, the out plate 970 may actually be a part that companion animals scratch.

The base plate 960 may face the surface of the rod assembly 400 when the first scratcher 950a is folded. A link block 980 connected to the connection part 918a may be disposed above the base plate 960 . The link block 980 allows the upper portion of the base plate 960 and the connecting portion 918a to be rotatably connected to each other. To this end, the link block 980 is provided with a rotating shaft portion 985, and the rotating shaft portion 985 can be rotatably coupled to the connecting portion 918a. The link block 980 may be integrated with the base plate 960 or may be separate from the base plate 960 .

The out plate 970 stacked on the base plate 960 may rotate together with the base plate 960 . In a state in which the first scratcher 950a is unfolded, a companion animal may scratch the surface of the out plate 970 . The surface of the out plate 970 may be made of various materials such as paper, fiber, or wood. When the out plate 970 is worn, it can be separated from the base plate 960 and replaced. Alternatively, the out plate 970 may be integrally formed with the base plate 960 .

The total length of the first scratcher 950a may be equal to or shorter than the length of the step station 918 . In this case, when the first scratcher 950a is folded, one end of the first scratcher 950a may not protrude more than one end of the step station 918 . Referring to FIG. 47, when the first scratcher 950a is folded, it can adhere to the lower part of the step station 918 and does not protrude further from the step station 918. can increase coherence.

Referring to FIG. 39 again, a link block 980 may be disposed above the base plate 960. The link block 980 is connected to the connection part 918a of the step station 918. When the rotating shaft portion 985 of the link block 980 is inserted into the connecting portion 918a, the entire first scratcher 950a may be rotated around the rotating shaft portion 985.

Reference FIG. 46 shows the first scratcher 950a and the second scratcher 950b in an unfolded state, respectively. In this state, when the first scratcher 950a and the second scratcher 950b are rotated in the directions of the arrows ① and ②, respectively, the first scratcher 950a and the second scratcher 950b are in a folded state. 47 shows the first scratcher 950a and the second scratcher 950b in a folded state.

At this time, although not shown, a fixed magnet may be embedded in one end of the first scratcher 950a. The stationary magnet enables the first scratcher 950a to be fixed to the step station 918 in a folded state. To this end, the step station 918 may be provided with a counter magnet or a metal member corresponding to the fixed magnet. Conversely, a metal member may be provided on the first scratcher 950a, and a fixed magnet may be disposed on the step station 918. Alternatively, a torsion spring may be provided in the link block 980 to provide elastic force to the first scratcher 950a to maintain the first scratcher 950a in a folded state.

On the other hand, the housing space (S) in the housing module 100 may be omitted. As shown in FIG. 48, the housing module 100 simply provides a space in which the thermostat 200 can be installed, and the tower of this embodiment is placed at a specific location, for example, on a ceiling (C) or a wall ( W) can be fixed. If the housing space (S) in the housing module 100 is omitted, companion animals can stay in the seat parts 918 and 920.

Also, the housing module 100 itself may be regarded as a kind of temperature control device. Since the temperature control device 200 disposed in the housing module 100 can generate cold or warm air and discharge it to the air passage, the housing module 100 serves as a temperature control device.

Also, as shown in FIG. 49 , the housing module 100 may be disposed below the rod assembly 400 . In this case, the cold air or warm air generated in the housing module 100 may move upward along the air passage formed inside the rod assembly 400 . The housing module 100 may be installed on the floor (G, see FIG. 3) or on a wall surface (W) spaced apart from the floor (G).

On the other hand, the tower of the present invention does not necessarily have to be built along the direction of gravity as shown in FIGS. 1, 48 or 49. For example, the tower of the present invention may be used in a state in which it is laid in a left-right direction based on the drawings.

The above description is merely an example of the technical idea of the present invention, and various modifications and variations can be made to those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but to explain, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed according to the claims below, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

100: housing module 110: case cover
111: lower cover plate 113: cover side plate
114,115: cover side plate hole 117: cover top plate hole
120: outer case 122: case opening
123: out side plate 124: front opening
125: Out side plate hole 126: Out top plate
127: Out top plate hole 129: Door support end
130: inner case 131: inner lower plate
132: lower open hole 133: inner side plate
134: entrance 134a: door mounting part
135: side communication hole 136: inner top plate
137: motor mounting part 138: inner thick plate
139: door stopper 140: opening and closing motor
145: opening and closing gear 150: door
151: door body 153: door rotation shaft
155: rotary drive unit 155a: drive gear
156: connecting arm 160: insulation member
161: lower insulation plate 162: lower connection hole
163: insulated side plate 164: insulated inlet
165: insulation side plate hole 165a: mounting space
167: motor mounting groove 168: insulation plate
169: connection flange 169a: connection space
180: control unit 183: external sensor
190: bracket module 200: temperature controller
210: housing cover 211: device housing
212: recovery unit 213: mounting plate
214: heat sink 218: cold sink
260: duct guide 261: guide flange
262: guide entrance 263a: first guide exit
263b: second guide exit 300: duct fan
310: fan assembly 320: fan housing
400: rod assembly 410: first rod body
500: first rod 510: first rod body
515: lift case 518: first lift slot
530: first sealing end 550: first rod discharge hole
600: second rod 610: second rod body
618: second lift slot 630: second upper ceiling end
640: second lower sealing end 650: second rod discharge hole
700: third rod 710: third rod body
730: third sealing end 750: third rod discharge hole
800a: first seat lifting device 800b: second seat lifting device
810: lift housing 811: lift space
812: lift guide 818: communication slot
820: lift drive unit 821: drive box
823: motor gear 824: driven gear
825: reduction gear 826: main gear
830: lift bar 835: lift gear
837: elevating bridge 900: seat assembly
918: step station 918a: connection
920: seat station 950a: first scratcher
950b: second scratcher 960: base plate
970: out plate 980: link block
DC: communication cap DC': cap hole
F1: 1st control fan F2: 2nd control fan
S: housing space

Claims (18)

A rod assembly in which at least two rods are overlapped and connected to have a variable length;
A seat portion installed on the rod and configured to be adjusted in position by movement of the rod;
A tower for companion animals comprising a scratcher installed on the rod side, rotatable at a predetermined angle around a rotation axis, and having an out plate detachably on a base plate.
The tower for companion animals of claim 1, wherein the scratcher is rotatable in a range between an outer surface of the rod and one surface of the seat portion.
The tower for companion animals of claim 1, wherein the base plate faces the outer surface of the rod and the outer plate is exposed to the outside when the scratcher approaches the outer surface of the rod.
The tower for companion animals of claim 1, wherein the scratcher is rotatably installed on the seat part about the rotation axis.
The tower for companion animals of claim 4, wherein an elastic member is installed on the rotating shaft so that the scratcher adheres to the surface of the rod or one surface of the seat part.
The tower for companion animals of claim 4, wherein a magnet is installed or a magnet and a metal member are installed at positions corresponding to each other between the scratcher and the rod or the scratcher and the sheet portion.
The tower for companion animals of claim 1, wherein the length of the scratcher is equal to or shorter than the length of the seat portion.
The tower for companion animals of claim 1, wherein the surface of the out plate is made of at least one of paper, fiber, and wood.
A rod assembly in which at least two rods are overlapped and connected to have a variable length and are installed vertically;
A seat portion installed on the rod to be movable in the longitudinal direction of the rod;
A tower for companion animals comprising a scratcher that is rotatable at a predetermined angle around the axis of rotation of the seat portion and is detachably provided with an out plate on a base plate.
The tower for companion animals of claim 9, wherein an elastic member is installed on the rotating shaft so that the scratcher adheres to the surface of the rod or one surface of the seat part.
The tower for companion animals of claim 9, wherein a magnet or a magnet and a metal member are installed at positions corresponding to the scratcher and the rod or the scratcher and the sheet portion, respectively.
The tower for companion animals of claim 10 or claim 11, wherein the length of the scratcher is equal to or shorter than the length of the seat portion.
The tower for companion animals of claim 12, wherein the scratcher is used by a companion animal in a state where the base plate faces the surface of the rod and the out plate is exposed.
The tower for companion animals of claim 13, wherein the surface of the out plate is made of at least one of paper, fiber, and wood.
The tower for companion animals of claim 9, wherein a seat lifting device for lifting the seat portion is installed inside the rod.
The method according to claim 15, wherein the seat lifting device passes through a lift driver installed inside the rod, a lift bar lifted inside the rod by the lift driver, and an lift slot integrally provided with the lift bar and formed in the rod. A tower for companion animals that includes a lift bridge connected to the seat.
The method according to claim 16, wherein the lifting drive unit includes a driving box, a lifting motor installed inside the driving box, and gears that transmit driving force of the lifting motor, and a worm is installed on a rotating shaft of the lifting motor to A tower for pets that meshes with one worm gear.
The tower for companion animals of claim 17, wherein the lifting bar is a rack gear.

Images