201114463 六、發明說明: 【發明所屬之技術領域】 本發明是關於一種立體迷宮裝置,特別是有關於一種 可調整難度的立體迷宮裝置。 【先前技術】 伴隨著魔術方塊的發明,各種益智玩具也如雨後春筍 般不斷地被研發出來。而各種益智玩具不僅可用以作為腦 力訓練的功用,更可用以打發空閒時間。因此,益智玩具 在現代人生活中的重要性也逐漸提高。 然而,現行大多數益智玩具都有難度變化性不足的問 題。換言之,益智玩具的難度不是過於困難就是過於簡 單,無法自由調整使得消費者不易挑選程度適合自己的益 智玩具,如此也大幅降低消費者的購買意願。 再者,現行益智玩具大多僅有益智性,而無其他附加 功能,無法於玩益智玩具的同時達到其他例如保健功能。 【發明内容】 有鑑於上述課題,本發明之目的為提供一種難度變化 性多,能夠自由調整難度的立體迷宮裝置。 有鑑於上述課題,本發明之其他目的為提供一種能夠 剌激手指尖端,達到保健功能的立體迷宮裝置。 為達上述目的,依據本發明之一種立體迷宮裝置包括 一内筒、一外環以及一導引件。内筒具有至少二段,該些 段相對為可旋轉的並分別具有至少二區域,各區域包含設 201114463 置於内筒表面之一迷宮槽,該些段可相對旋轉而具有一第 一相對角度與一.第二相對角度。外環可旋轉地及可滑動地 套設在内筒,導引件設置在外環内壁並延伸至該些迷宮槽 其中之一,以隨著外環旋轉及滑動而沿迷宮槽移動。其 中,當内筒之該些段間為第一相對角度時,立體迷宮裝置 具有至少一第一解答路徑,當内筒之該些段間為第二相對 角度時,立體迷宮裝置具有至少一第二解答路徑,上述至 少一第一解答路徑所經之該些區域數量大於上述至少一 第二解答路徑所經之該些區域數量。 在本發明一實施例中,位於相異段但相鄰的該些迷宮 槽,分別具有開口端彼此對準連接。 在本發明一實施例中,位於相同段且相鄰的該些迷宮 槽,分別具有開口端彼此對準連接。 在本發明一實施例中,外環的外表面設置有複數個凸 點或複數個凸條。 在本發明一實施例中,外環更具有一透明區,導引件 設置在透明區’以猎由透明區觀察導引件沿迷宮槽移動的 情形。其中,透明區可為一可調整大小的區域。 在本發明一實施例中,各段的該些區域具有相異的顏 色。 承上所述,依據本發明之一種立體迷宮裝置將外環可 旋轉地及可滑動地套設在内筒,内筒具有至少二可相對旋 轉的段,各段具有至少二區域,且各區域具有一迷宮槽, 並藉由設置在外環的導引件隨著外環旋轉及滑動而沿迷 201114463 宮槽中移動。因此’使用者可旋轉及滑動外環設法使導引 件經由解答路徑走出迷宮槽,以使外環與内筒分離。另 外,該些區域分別會具有不同的㈣度,若解答二徑需經 過較多的區域,即表示此解答路徑較難。再者,旋轉該^ 段可排列出不同的區域組合,以形成不同難度的迷宮組 合’藉此可提供使用者難度變化性多且能夠自由調整難度 的立體迷宮裝置。 又 外環可更具有透明區,導引件設置在透明區,以讓使 用者可藉由透明區觀察導引件沿迷宮槽移動的情形。因 此’可藉由調整透明區的大小,例如加大透明區增加❹ 雜圍或者縮小透籠❹可視·,來調整本發明之立體 迷宮裝置的難易度。另外,藉由外環外表面所設置的複數 個凸點或複數個凸條’能夠提供玩立體迷宮的同時刺激手 指尖端,進而達到活絡腦部神經及訓練手眼協調之保健功 能0 【實施方式】 以下將參照㈣圖式,說縣本發明較佳實施例之一 種ί體逑宮裝置,其中㈣料件將以相_參照符號加 以說明。 清參照圖1Α及圖1Β所千,甘士 ^ 口 ^所不其中圖1A為本發明較佳 貫域之立體逑宮裝置1示意:圖,圖為立體迷宮裝置! 的使用狀態示意圖。立體迷宮裝置1包括-内筒2、一外 環3及一導引件4。 201114463 内筒2具有至少-段 旋轉而具有-第-相2 =、22,該些段21、22可相對 i角度與一第二相對角声。音 疋,該些段21、22可相對旌艟94t 角度而/思的 ^ α 對凝轉疋指,段21可以是固定的, 而段22相對於段21是 疋U疋耵 的,而段21相對於雜22可以是固定 為可旋轉的。而第—相對;;可^轉的;或者段21、22皆 ^ ^ f角度與第二相對角度可以是相同 中,第-#斟"V且分別可以是任何預設角度,在本實施例 12〇Ϊ:= 相對角度分別可以是〇度、9。度、 度或240度,其非限制性。 〜各仪21、22分別具有不同難度之至少二區域。Α太 貫施例中,以段21、22八,丨丨目士 _ ^、—本 刀別具有二個區域作說明,其中 具有不同難度之三個區域211,而段22同樣具有不 心區域221 ’然其非限制性。當然,不同難度 仏域的個數依要求亦可大於三個 歸的該些區域211以及段22上不_度的紗區上不门 =別具有相同或相異的顏色,若利用相異的顏二 了錯由不同的顏色來區分難易度,例如在相同的段21或 2上’利用不同顏色區分難易度,但不同段21及22上, 相同顏色的區域211、221表千姑π雜危 非限制性。 度’上述為舉例性 各區域2U、221並具有一逑宮槽9。各迷宮槽9可由 不同延伸方向的複數個槽道構成,例如由橫 :的複數個槽道91及縱向(轴向)延伸的複 構成,且各迷宮槽9具有至少二開口端93分別作為出入 201114463 口。需注意的是,各區域211、221亦可具有二個或二個 以上分別獨立不連接的迷宮檜9。當然,依不同的難度設 計及要求,各迷宮槽9亦可由斜向延伸或者弧形的槽道所 構成,且各迷宮槽9可具有二個以上的出入口。值得一提 的是,位於相同段21或22上相鄰的該些迷宮槽9,可以 分別具有一開口端93彼此對準連接。換言之,迷宮槽9 的開口端93並非一定得位於區域211、221的上侧及/或下 側,亦可位於區域211、221的左侧及/或右側,以與相鄰 區域211、221的迷宮槽9連接。 . 再者;需注意的是,位於相異段21及22但相鄰的迷 宮槽9分別具有開口端93彼此對準連接。換言之,段21 及段22相對旋轉後,分別位於段21及22上不同區域211、 221的迷宮槽9,即使變更排列組合後,不同段21及22 上的該些迷宮槽9仍具有開口端93彼此對準連接。藉此, 段21及22上不同的區域211、221即可有效地排列組合 形成更多不同的迷宮路徑,使用者可依據需要自由調整。 又,值得一提的是,在此段21中不同難度的三個區 域211各自所涵蓋的角度均相同(皆為120度),且段22 之三個區域221亦同,然其僅為實施例說明,並非限制性。 亦即,該些區域211、221所涵蓋的角度亦可不相同,例 如一個區域涵蓋的角度為180度,其他二個區域涵蓋的角 度為90度等,端以段21、22相對旋轉後,該些區域211、 221仍能對準連接以形成完整的迷宮路徑為考量。 需注意的是,由於各區域211、221的涵蓋角度為120 201114463 度,因此當段21相對於段22旋轉120度(即第一相對角 度)後會產生定位固定,接著段21再相對於段22旋轉12〇 度(即相對原點為240度(即第二相對角度))也會產生 定位固定,而段21再旋轉12〇度即會回到原點產生定位 固定。當然上述僅為舉例性,非用以限制本發明。再者, •k 21、22相對產生定位固定的方式例如可利用凸部/凹 部、卡勾/卡槽、楔形塊/楔形塊等方式或者其他可產生定 位固定的方式構成,在此不予以限制。 接著,請繼續參考圖1A至圖1β。其中,外環3係可 旋轉地tab!y)及可滑動地(slidably)套設在内筒2。 而導引件4設置於外環3的内壁並延伸至該些迷宮槽9其 中之-,以隨著外環3的旋轉及滑動而 了 ff實施财,導引件4例如是—凸塊或-凸柱,而夕^環 舁内同2是為可分離的(separabIe),但均不欲以此為限。 較佳實施例中’外環3更可具有-透明區 =件4設置在透㈣3卜以藉由透 移動的情形。再者,外環3之透明區: 例“ Ί周’大小的區域’藉由改變透明區31的大小, 增力,範圍或者縮小透明區㈣少 了視^’同樣可纏立體迷的難易度。 由解答路徑^者:旋轉及滑動外環3設法使導引件4經 筒2分離而术辻呂槽9 ’甚至進而使外環3移動而與内 ;;":::!2 ^ 0度、90度、⑽度、_度或其他預設 201114463 角度)時,立體迷宮裝置1具有至少一第一解答路徑,當 内筒2之該些段21、22間為第二相對角度(例如可以是0 度、90度、120度、240度或其他預設角度)時,立體迷 宮裝置1具有至少一第二解答路徑,第一解答路徑所經之 該些區域211、221的數量會大於第二解答路徑所經之該 些區域211、221的數量。 具體而言,當第一解答路徑與第二解答路徑皆為一個 時,則此第一解答路徑所經的該些區域211、221的數量 會大於此第二解答路徑所經的該些區域211、221的數量。 進一步來說,當立體迷宮裝置1具有複數個第一解答路徑 與複數個第二解答路徑時,則這些第一解答路徑中存在至 少一個第一主要解答路徑,而這些第二解答路徑中存在至 少一個第二主要解答路徑,此第一主要解答路徑與第二主 要解答路徑可為設計者預先設定。然而,本發明對此不作 任何限定。由此,此第一主要解答路徑所經的該些區域 2U、221的數量會大於第二主.要解答路徑所經的該些區域 211、221的數量。類似地,當第一解答路徑為一個,而第 二解答路徑為多個時,此第一解答路徑所經的該些區域 211、221的數量會大於第二主要解答路徑所經的該些區域 211、221的數量。反之亦然。. 換言之,該些區域211、221分別會具有不同的難易 度,而若解答路徑需經過較多的區域211、221,即相對表 示此解答路徑的變化較多,難度也有可能較難。同時,藉 由相對旋轉該些段21、22可排列出不同的區域211、221 201114463 組合,以形成涵蓋之區域211、221數量不同的解答路徑。 換否之,旋轉該些段21、22可形成更多不同難度的解答 路L,猎此可供使用者難度變化性多的立體迷宮裝置1。 如圖2所示,其為本發明較佳實施例之立體迷宮裝置 la另一態樣示意圖。立體迷宮裝置la的内筒仏具有三個 丰又21、22及23。因此,為增加迷宮的變化性,立體迷宮 裝置la亦可具有更多段,例如本實施例利用三個段、 22及23,且段21具有四個不同難度的區域211,段22具 鲁有四個不同難度的區域221以及段23具有四個難度不同 的區域231’藉此立體迷宮裝置la可形成4χ4χ4=64種的 逑宮組合。當然,立體迷宮裝置la亦可具有更多段或更多 區域’以形成更多種的迷宮組合。或者,該些段、22 及23也可以是可分離的,換言之,可以藉由拆換段2ι、 22及23來形成更多不同的迷宮組合。 需注意的是’立體迷宮裝置1&更可包含一柱體c,内 •筒2a套设於柱體C,該些段2卜22及23分別例如可為套 筒牙a又在柱體c上。柱體C表面沿圓周方向間隔設置有複 數個第一卡合部C1,且内筒2a之各段21、22及23的内 -壁對應該些第一卡合部C1設置有複數個第二卡合部(圖 中未表示)。第一卡合部C1及第二卡合部可為凸部/凹部、 卡勾/卡槽等組合,在此第一卡合部C1及第二卡合部以凸 部/凹部為例,其非限制性。 因此,當該些段21、22及23相對旋轉時,該些第二 卡合部與該些第一卡合部C1相互卡合而定義該些段21、 11 201114463 22及23間之第一相對角度與第二相對角度。也就是說, 例如在本實施例中,由於各區域211、221及231的涵蓋 角度為90度,因此當段21相對於段22旋轉90度(即第 一相對角度)後,第二卡合部與第一卡合部C1相互卡合 會產生定位固定,接著段21再相對於段22旋轉90度(即 相對原點為180度(即第二相對角度))第二卡合部與第 一卡合部C1相互卡合也會產生定位固定,當然段21可再 旋轉90度(即相對原點為270度)及180度以回到原點 產生定位固定。當然上述僅為舉例性,非用以限制本發明。 更甚者,該些區域21卜221及231也可以是可拆的, 換言之,該些區域211、221及231可以是殼體,藉由拆 換區域211、221及231來形成更多不同的迷宮組合。值 得一提的是,當然也可以是段21、22及23為不可拆換的, 而該些區域211、221及231是可拆的。 另外,在本實施例中,外環3 a的透明區31 a較大,藉 此可增加可視範圍,以降低立體迷宮裝置la的難易度。當 然,使用者可以更換不同透明區大小的外環來調整難易 度。再者,外環3a的外表面更設置有複數個凸點或複數個 凸條,在此以外環3a的外表面設置有複數個凸點32為例, 其非限制性。藉由外環3a外表面設置的該些凸點32,可 在使用者在玩立體迷宮裝置la的同時,刺激使用者的手指 尖端產生按摩的功效,進而達到保健功能。 綜上所述,依據本發明之一種立體迷宮裝置將外環可 旋轉地及可滑動地套設在内筒,内筒具有至少二可相對旋 12 201114463 轉的段,各段具有至少二區域,且各區域具有一迷宮槽, 藉由外環具有的導引件在迷宮槽中移動。因此,使用者可 - 移動外環設法使導引件經由解答路徑走出迷宮槽,以使外 環移動而與内筒分離。另外,該些區域分別會具有不同的 難易度,而若解答路徑需經過較多的區域,即表示此解答 路徑的變化較多,難度也有可能較難。再者,旋轉該些段 可排列出不同的區域組合,以形成不同難度的迷宮組合, 藉此可提供使用者難度變化性多且能夠自由調整難度的 • 立體迷宮裝置。 外環可更具有透明區,導引件設置在透明區。因此, 可藉由改變透明區的大小,例如加大透明區增加可視範圍 …或者縮小透明區減少可視範圍,來調整本發明之立體迷宮 裝置的難易度。另外,藉由外環外表面所設置的複數個凸 點或複數個凸條,能夠提供玩立體迷宮的同時刺激手指尖 端,進而達到活絡腦部神經及訓練手眼協調之保健功能。 $ 以上所述僅為舉例性,而非為限制性者。任何未脫離 本發明之精神與範疇,而對其進行之等效修改或變更,均 應包含於後附之申請專利範圍中。 【圖式簡單說明】 圖1A為本發明較佳實施例之立體迷宮裝置示意圖, 圖1B為如圖1A之立體迷宮裝置的使用狀態示意圖;以及 圖2為本發明較佳實施例之立體迷宮裝置另一態樣示 201114463 意圖。 【主要元件符號說明】 1、 la :立體迷宮裝置 2、 2a :内筒 2 卜 22、23 :段 211、22卜 231 :區域 3、 3 a :外環 31、31a :透明區 ^ 9. : Λ f J: 4 :導引件 9 :迷宮槽 91、92 :槽道 93 :開口端 C :柱體 C1 :第一卡合部201114463 VI. Description of the Invention: [Technical Field] The present invention relates to a three-dimensional labyrinth apparatus, and more particularly to a three-dimensional labyrinth apparatus capable of adjusting difficulty. [Prior Art] Along with the invention of the magic square, various educational toys have been continuously developed. And a variety of educational toys can be used not only as a function of brain training, but also to spend free time. Therefore, the importance of educational toys in modern people's lives has gradually increased. However, most of the current educational toys have problems of insufficient variability. In other words, the difficulty of educational toys is not too difficult or too simple, and it is not easy to adjust so that consumers are not easy to choose the right toys that are suitable for them, which also greatly reduces consumers' willingness to purchase. Moreover, most of the current educational toys are only ingenious, and there are no other additional functions, and it is impossible to play other educational functions while playing educational toys. SUMMARY OF THE INVENTION In view of the above problems, an object of the present invention is to provide a three-dimensional labyrinth apparatus which is highly variable in difficulty and capable of freely adjusting difficulty. In view of the above problems, another object of the present invention is to provide a three-dimensional labyrinth device capable of stimulating a finger tip and achieving a health care function. To achieve the above object, a three-dimensional labyrinth apparatus according to the present invention comprises an inner cylinder, an outer ring and a guide. The inner cylinder has at least two segments, the segments being relatively rotatable and each having at least two regions, each region comprising a labyrinth groove disposed on the inner cylinder surface of 201114463, the segments being relatively rotatable to have a first relative angle With a second relative angle. The outer ring is rotatably and slidably sleeved in the inner cylinder, and the guiding member is disposed on the inner wall of the outer ring and extends to one of the labyrinth slots to move along the labyrinth slot as the outer ring rotates and slides. Wherein, when the segments of the inner cylinder are at a first relative angle, the three-dimensional labyrinth device has at least one first solution path, and when the segments of the inner cylinder are at a second relative angle, the three-dimensional labyrinth device has at least one The second solution path, the number of the regions through which the at least one first solution path passes is greater than the number of regions through which the at least one second solution path passes. In an embodiment of the invention, the plurality of labyrinths located adjacent to each other but adjacent to each other have open ends that are aligned with each other. In an embodiment of the invention, the plurality of labyrinth slots located in the same segment and adjacent to each other have open ends that are aligned with each other. In an embodiment of the invention, the outer surface of the outer ring is provided with a plurality of bumps or a plurality of ridges. In an embodiment of the invention, the outer ring further has a transparent region, and the guide member is disposed in the transparent region </ RTI> to hunt the transparent portion to observe the guide member moving along the labyrinth slot. The transparent area can be a resizable area. In an embodiment of the invention, the regions of each segment have distinct colors. According to the present invention, a three-dimensional labyrinth apparatus according to the present invention rotatably and slidably sleeves an outer ring, the inner cylinder having at least two relatively rotatable segments, each segment having at least two regions, and each region It has a labyrinth slot and moves along the 201114463 sulcus by means of a guide disposed on the outer ring as the outer ring rotates and slides. Thus the user can rotate and slide the outer ring to try to get the guide out of the labyrinth slot via the solution path to separate the outer ring from the inner barrel. In addition, the regions will have different (four) degrees. If the answer to the two paths has to pass through more regions, it means that the solution path is difficult. Furthermore, the rotation of the segment can arrange different combinations of regions to form a labyrinth combination of different difficulty', thereby providing a three-dimensional labyrinth device with many user variability and freely adjustable difficulty. Further, the outer ring may have a transparent area, and the guiding member is disposed in the transparent area to allow the user to observe the movement of the guiding member along the labyrinth groove by the transparent area. Therefore, the difficulty of the three-dimensional labyrinth apparatus of the present invention can be adjusted by adjusting the size of the transparent area, for example, increasing the transparent area to increase the circumference or reducing the size of the transparent frame. In addition, the plurality of bumps or a plurality of ridges provided by the outer surface of the outer ring can provide a three-dimensional labyrinth while stimulating the tip of the finger, thereby achieving a health function of activating the brain nerve and training hand-eye coordination. Hereinafter, referring to the (four) diagram, a preferred embodiment of the present invention will be described, wherein (iv) the material will be described with reference numerals. BRIEF DESCRIPTION OF THE DRAWINGS Referring to Fig. 1 and Fig. 1 , ,, 甘 士 口 所 图 图 图 图 图 图 图 图 图 图 图 图 图 图 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 Schematic diagram of the state of use. The three-dimensional labyrinth apparatus 1 includes an inner cylinder 2, an outer ring 3, and a guide member 4. 201114463 The inner cylinder 2 has at least a segment of rotation and has a - phase -2 =, 22, and the segments 21, 22 are acoustically opposite to an i-angle. Tone, the segments 21, 22 can be 旌艟 旌艟 旌艟 旌艟 旌艟 旌艟 α α α , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , , 21 may be fixed to be rotatable relative to the miscellaneous 22. And the first-relative;; can be rotated; or the segments 21, 22 are ^ ^ f angle and the second relative angle can be the same, the first -#斟" V and respectively can be any preset angle, in this implementation Example 12:: The relative angles can be 〇, 9, respectively. Degree, degree or 240 degrees, which is not limiting. ~ Each of the instruments 21, 22 has at least two regions of different difficulty. In the example of the sacred sacred case, the segment 21, 22, 丨丨, _ ^, - this knife has two areas for description, in which there are three areas 211 of different difficulty, and the section 22 also has an unintentional area 221 'Rather, it is not restrictive. Of course, the number of different difficulty domains may be greater than the three regions 211 and the segment 22 may not have the same or different colors, if different colors are used. The difference between the two colors is to distinguish the difficulty. For example, in the same segment 21 or 2, the difficulty is distinguished by different colors, but in the different segments 21 and 22, the regions 211 and 221 of the same color are different. Risk is not restrictive. The above is an exemplary area 2U, 221 and has a sacral groove 9. Each of the labyrinth slots 9 may be formed by a plurality of channels in different extending directions, for example, a plurality of channels 91 of the horizontal direction and a plurality of longitudinally extending (axial directions), and each of the labyrinth grooves 9 has at least two open ends 93 as the accesses. 201114463 mouth. It should be noted that each of the regions 211, 221 may also have two or more labyrinths 9 that are independently connected. Of course, depending on the difficulty design and requirements, each of the labyrinth slots 9 may also be formed by obliquely extending or curved channels, and each of the labyrinth slots 9 may have more than two entrances and exits. It is worth mentioning that the labyrinth slots 9 adjacent to each other on the same section 21 or 22 may have an open end 93 aligned with each other. In other words, the open end 93 of the labyrinth slot 9 is not necessarily located on the upper side and/or the lower side of the regions 211, 221, and may be located on the left side and/or the right side of the regions 211, 221 to be adjacent to the adjacent regions 211, 221. The labyrinth slot 9 is connected. Further, it should be noted that the adjacent vertices 9 and 22, but adjacent to each other, have open ends 93 that are aligned with each other. In other words, after the segments 21 and 22 are relatively rotated, the labyrinth slots 9 in the different regions 211, 221 on the segments 21 and 22, respectively, even after the arrangement and combination, the labyrinth slots 9 on the different segments 21 and 22 have open ends. 93 are aligned with each other. Thereby, the different regions 211, 221 on the segments 21 and 22 can be effectively arranged and combined to form more different labyrinth paths, and the user can freely adjust as needed. Moreover, it is worth mentioning that the angles covered by the three regions 211 of different difficulty levels in this segment 21 are the same (both 120 degrees), and the three regions 221 of the segment 22 are the same, but only for implementation. The examples are not limiting. That is, the angles covered by the regions 211, 221 may also be different, for example, the angle covered by one region is 180 degrees, the angles covered by the other two regions are 90 degrees, etc., and the ends are rotated relative to the segments 21, 22, These areas 211, 221 can still be aligned to form a complete labyrinth path. It should be noted that since the coverage angle of each region 211, 221 is 120 201114463 degrees, when the segment 21 is rotated by 120 degrees (ie, the first relative angle) with respect to the segment 22, positioning fixation is generated, and then the segment 21 is then relative to the segment. 22 rotation 12 degrees (that is, 240 degrees relative to the origin (ie, the second relative angle)) will also produce a fixed positioning, and the segment 21 will rotate 12 degrees to return to the origin to produce a fixed positioning. Of course, the foregoing is merely exemplary and is not intended to limit the invention. Furthermore, the manner in which the k 21 and 22 are fixed relative to each other can be formed by, for example, a convex portion/recess, a hook/card slot, a wedge block/wedge block, or the like, which can be fixed by positioning, and is not limited herein. . Next, please continue to refer to FIG. 1A to FIG. The outer ring 3 is rotatably tab!y) and slidably sleeved in the inner tube 2. The guiding member 4 is disposed on the inner wall of the outer ring 3 and extends to the middle of the plurality of labyrinth slots 9 for performing the rotation and sliding of the outer ring 3, and the guiding member 4 is, for example, a bump or - the stud, and the inner ring is the same as the separable (separabIe), but they are not intended to be limited. In the preferred embodiment, the outer ring 3 may have a transparent region = the member 4 is disposed in a transparent manner. Furthermore, the transparent area of the outer ring 3: for example, the "area of the size of the circumference" is changed by the size of the transparent area 31, the force is increased, the range is narrowed, or the transparent area is reduced (4). By the solution path ^: rotating and sliding the outer ring 3 to try to separate the guide 4 through the barrel 2 to smash the groove 9' and even the outer ring 3 to move inside;;":::!2 ^ When the degree of 0 degree, 90 degrees, (10) degrees, _ degrees or other presets 201114463 angle), the three-dimensional labyrinth device 1 has at least one first solution path, when the segments 21, 22 of the inner cylinder 2 are at a second relative angle ( For example, when the angle is 0 degrees, 90 degrees, 120 degrees, 240 degrees or other preset angles, the stereo maze device 1 has at least one second solution path, and the number of the regions 211, 221 through which the first solution path passes More than the number of the regions 211, 221 through which the second solution path passes. Specifically, when the first solution path and the second solution path are both, the regions 211 through which the first solution path passes, The number of 221 will be greater than the number of the regions 211, 221 through which the second solution path passes. Further, when the stereo maze device 1 has a plurality of first solution paths and a plurality of second solution paths, at least one first main solution path exists in the first solution paths, and the second solution paths exist in the second solution paths. At least one second primary solution path, the first primary solution path and the second primary solution path may be pre-set by the designer. However, the present invention does not limit this. Therefore, the first primary solution path passes through The number of the regions 2U, 221 may be greater than the number of the regions 211, 221 through which the path is to be solved. Similarly, when the first solution path is one and the second solution path is multiple, this The number of the regions 211, 221 through which the first solution path passes may be greater than the number of the regions 211, 221 through which the second primary solution path passes. Vice versa. In other words, the regions 211, 221 respectively have Different difficulty levels, and if the solution path needs to pass through more areas 211, 221, that is, relatively more changes in the path of the solution, the difficulty may be more difficult. Relatively rotating the segments 21, 22 may arrange different combinations of regions 211, 221 201114463 to form a solution path of different numbers of the regions 211, 221 covered. Alternatively, rotating the segments 21, 22 may form more differences. Difficult answer road L, hunting this three-dimensional labyrinth device 1 which is more versatile in user's difficulty. As shown in Fig. 2, it is another schematic diagram of a three-dimensional labyrinth device la according to a preferred embodiment of the present invention. The inner cylinder of la has three abundances 21, 22 and 23. Therefore, in order to increase the variability of the labyrinth, the three-dimensional labyrinth device la may have more segments, for example, three segments, 22 and 23, and segments are used in this embodiment. 21 has four regions 211 of different difficulty levels, segment 22 has regions 221 with four different difficulty levels, and segment 23 has four regions 231' with different difficulty levels, whereby the three-dimensional labyrinth device la can form a combination of 4χ4χ4=64 species . Of course, the three-dimensional labyrinth device la may also have more or more zones' to form a more diverse combination of labyrinths. Alternatively, the segments, 22 and 23 may also be separable, in other words, more different labyrinth combinations may be formed by splitting segments 2, 22 and 23. It should be noted that the 'stereo labyrinth device 1& can further include a cylinder c, and the inner cylinder 2a is sleeved on the cylinder C, and the segments 2 and 22 and 23 can respectively be sleeve teeth a and cylinders c, respectively. on. A plurality of first engaging portions C1 are disposed on the surface of the cylinder C at intervals in the circumferential direction, and the inner-walls of the segments 21, 22 and 23 of the inner cylinder 2a are provided with a plurality of second portions corresponding to the first engaging portions C1. The engagement part (not shown). The first engaging portion C1 and the second engaging portion may be a combination of a convex portion/recessed portion and a hook/slot, and the first engaging portion C1 and the second engaging portion are exemplified by a convex portion/a concave portion. Not limited. Therefore, when the segments 21, 22, and 23 are relatively rotated, the second engaging portions and the first engaging portions C1 are engaged with each other to define the first of the segments 21, 11 201114463 22 and 23 The relative angle is opposite to the second angle. That is, for example, in the present embodiment, since the coverage angle of each of the regions 211, 221, and 231 is 90 degrees, after the segment 21 is rotated by 90 degrees with respect to the segment 22 (ie, the first relative angle), the second engagement is performed. The engagement of the first engaging portion C1 with the first engaging portion C1 will result in positioning and fixing, and then the segment 21 is rotated 90 degrees with respect to the segment 22 (ie, 180 degrees relative to the origin (ie, the second relative angle)) the second engaging portion and the first portion When the engaging portions C1 are engaged with each other, the positioning is fixed. Of course, the segment 21 can be rotated by 90 degrees (that is, 270 degrees with respect to the origin) and 180 degrees to return to the origin to generate the positioning and fixing. Of course, the foregoing is merely exemplary and is not intended to limit the invention. Moreover, the regions 21 221 and 231 may also be detachable. In other words, the regions 211, 221, and 231 may be shells, and the regions 211, 221, and 231 are replaced to form more different ones. Maze combination. It is worth mentioning that, of course, the segments 21, 22 and 23 are non-removable, and the regions 211, 221 and 231 are detachable. Further, in the present embodiment, the transparent area 31a of the outer ring 3a is large, whereby the visual range can be increased to reduce the difficulty of the three-dimensional labyrinth device la. Of course, the user can change the outer ring of different transparent area size to adjust the difficulty. Further, the outer surface of the outer ring 3a is further provided with a plurality of bumps or a plurality of ridges, and the outer surface of the outer ring 3a is provided with a plurality of bumps 32 as an example, which is not limited. The bumps 32 provided on the outer surface of the outer ring 3a can stimulate the user's finger tip to generate a massage effect while playing the stereo labyrinth device la, thereby achieving the health care function. In summary, a three-dimensional labyrinth apparatus according to the present invention rotatably and slidably sleeves an outer ring in an inner cylinder, the inner cylinder having at least two segments that are relatively rotatable 12 201114463, each segment having at least two regions. And each region has a labyrinth slot that is moved in the labyrinth slot by a guide member having an outer ring. Thus, the user can - move the outer ring to try to get the guide out of the labyrinth slot via the answer path to move the outer ring apart from the inner barrel. In addition, the regions will have different difficulty levels, and if the solution path needs to pass through more regions, it means that the solution path has more changes, and the difficulty may be more difficult. Furthermore, by rotating the segments, different combinations of regions can be arranged to form a combination of labyrinths of different difficulty, thereby providing a three-dimensional labyrinth device that is more versatile in user difficulty and can be freely adjusted. The outer ring may have a transparent area and the guide member is disposed in the transparent area. Therefore, the difficulty of the three-dimensional labyrinth apparatus of the present invention can be adjusted by changing the size of the transparent area, for example, increasing the transparent area to increase the visible range ... or reducing the transparent area to reduce the visible range. In addition, by using a plurality of bumps or a plurality of ridges provided on the outer surface of the outer ring, it is possible to provide a three-dimensional labyrinth while stimulating the tip of the finger, thereby achieving a health care function of activating the brain nerve and training hand-eye coordination. The above description is for illustrative purposes only and is not a limitation. Any equivalent modifications or alterations to the spirit and scope of the present invention are intended to be included in the scope of the appended claims. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1A is a schematic view of a three-dimensional labyrinth apparatus according to a preferred embodiment of the present invention, FIG. 1B is a schematic view showing a state of use of the three-dimensional labyrinth apparatus of FIG. 1A; and FIG. 2 is a three-dimensional labyrinth apparatus according to a preferred embodiment of the present invention. Another aspect shows the intention of 201114463. [Description of main component symbols] 1. la: three-dimensional labyrinth device 2, 2a: inner cylinder 2 Bu 22, 23: segment 211, 22 231: region 3, 3 a: outer ring 31, 31a: transparent region ^ 9. : Λ f J: 4 : Guide member 9 : Labyrinth groove 91 , 92 : Channel 93 : Open end C : Column C1 : First engaging portion