Deprecated: The each() function is deprecated. This message will be suppressed on further calls in /home/zhenxiangba/zhenxiangba.com/public_html/phproxy-improved-master/index.php on line 456
JP4814780B2 - Thermal storage type gas processor and thermal storage type gas processing equipment using the same - Google Patents
[go: Go Back, main page]

JP4814780B2 - Thermal storage type gas processor and thermal storage type gas processing equipment using the same - Google Patents

Thermal storage type gas processor and thermal storage type gas processing equipment using the same Download PDF

Info

Publication number
JP4814780B2
JP4814780B2 JP2006345408A JP2006345408A JP4814780B2 JP 4814780 B2 JP4814780 B2 JP 4814780B2 JP 2006345408 A JP2006345408 A JP 2006345408A JP 2006345408 A JP2006345408 A JP 2006345408A JP 4814780 B2 JP4814780 B2 JP 4814780B2
Authority
JP
Japan
Prior art keywords
gas
supply
chamber
discharge
heat storage
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
JP2006345408A
Other languages
Japanese (ja)
Other versions
JP2008157510A (en
Inventor
朋孝 三輪
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Taikisha Ltd
Original Assignee
Taikisha Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Taikisha Ltd filed Critical Taikisha Ltd
Priority to JP2006345408A priority Critical patent/JP4814780B2/en
Publication of JP2008157510A publication Critical patent/JP2008157510A/en
Application granted granted Critical
Publication of JP4814780B2 publication Critical patent/JP4814780B2/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Landscapes

  • Incineration Of Waste (AREA)

Description

本発明は汚染物質を含む排ガスの浄化処理や悪臭物質を含む排ガスの脱臭処理などに用いる蓄熱式ガス処理器に関し、詳しくは、
蓄熱材を収容した複数の蓄熱室と、被処理ガスを燃焼させる燃焼手段を備えた燃焼室と、前記蓄熱室の各々について蓄熱室を介して前記燃焼室に導入される被処理ガス及び燃焼室から蓄熱室を介して導出される処理済ガスを通過させる複数の給排室とを器体内部に形成し、
前記複数の蓄熱室を器体内部の上下中間部において横方向に並べて、各蓄熱室の上端又は下端のうちの一端を前記燃焼室に連通させ、且つ、各蓄熱室の他端を前記給排室の各々に個別に連通させる構造にするとともに、
前記給排室の各々について給排室を介して器体外部から前記燃焼室に被処理ガスを導入する被処理ガス導入状態と給排室を介して器体外部に処理済ガスを導出する処理済ガス導出状態とに交互的に切換可能な複数のガス給排路の各々に対する器体接続口部を形成してある蓄熱式ガス処理器及びそれを用いた蓄熱式ガス処理設備に関する。
The present invention relates to a regenerative gas processor used for purifying exhaust gas containing pollutants and deodorizing exhaust gas containing malodorous substances.
A plurality of heat storage chambers containing a heat storage material, a combustion chamber provided with combustion means for combusting a gas to be processed, and a gas to be processed and a combustion chamber introduced into the combustion chamber via the heat storage chamber for each of the heat storage chambers A plurality of supply and discharge chambers through which the processed gas derived from the heat storage chamber is passed are formed inside the container body,
The plurality of heat storage chambers are arranged in the horizontal direction at the upper and lower intermediate portions inside the body, and one end of each heat storage chamber is communicated with the combustion chamber, and the other end of each heat storage chamber is connected to the supply / discharge In addition to a structure that allows each room to communicate individually,
For each of the supply / exhaust chambers, a process gas introduction state in which the process gas is introduced into the combustion chamber from the outside of the container through the supply / discharge chamber, and a process for deriving the processed gas to the outside of the container through the supply / discharge chamber The present invention relates to a regenerative gas processor having a container connection port for each of a plurality of gas supply / exhaust passages that can be alternately switched to a spent gas derivation state, and a regenerative gas processing facility using the same.

この種の蓄熱式ガス処理器は、器体接続口部に接続されるガス給排路の一部から導入される被処理ガスを一部の給排室を介して一部の蓄熱室に通過させて燃焼室に至らせ、この燃焼室において被処理ガス中の汚染物質や悪臭物質などを燃焼により処理するとともに、燃焼室で処理後の処理済ガスを他の蓄熱室に通過させて、その蓄熱室の収容蓄熱材に対し蓄熱を行わせた後、他の給排室を介して他のガス給排路に導出する。   This type of regenerative gas processor passes the gas to be treated introduced from a part of the gas supply / exhaust passage connected to the body connection port to a part of the heat storage chamber through a part of the supply / discharge chamber. In this combustion chamber, the pollutants and malodorous substances in the gas to be treated are treated by combustion, and the treated gas after treatment in the combustion chamber is passed to another heat storage chamber, After heat storage is performed on the stored heat storage material in the heat storage chamber, the heat is stored in another gas supply / discharge path through another supply / discharge chamber.

そして、この処理においてガス給排路を被処理ガス導入状態と処理済ガス導出状態とに交互的に切り換えることにより、処理済ガスの通過をもって先に蓄熱した蓄熱材により被処理ガスを各蓄熱室の通過過程で予熱して、熱効率の向上を図ることを可能にしている。   In this process, the gas supply / exhaust path is alternately switched between the treated gas introduction state and the treated gas derivation state, so that the treated gas is stored in each heat storage chamber by the heat storage material previously stored with the passage of the treated gas. It is possible to improve the thermal efficiency by preheating in the passage process.

ところで、従来、この種の蓄熱式ガス処理器では、ガス給排路に対する器体接続口部を器体の底側壁部に形成する構造を採っていた。(例えば、下記特許文献1参照)
特開2005−61675
By the way, conventionally, this type of regenerative gas processor employs a structure in which a vessel connection port portion for a gas supply / discharge path is formed on the bottom side wall portion of the vessel body. (For example, see Patent Document 1 below)
JP-A-2005-61675

しかしながら、ガス給排路に対する器体接続口部を底側壁部に形成する上記の如き従来の構造では、ガス供給路を器体下外方空間から器体接続口部に接続することになるため、その接続空間を確保するのに、器体設置面に対して相当浮かせた状態で器体を設置しなればならないことから、もともと器体が比較的大型であるにもかかわらず、実質的な器体高さ(つまり、器体設置面から器体上部までの高さ)が相当高くなってしまい、そのことで、例えば、既存の建物内部や既存の乾燥炉の下部空間などの設置スペースに対して設置し難くなる問題があった。   However, in the conventional structure as described above in which the body connection port portion for the gas supply / discharge path is formed in the bottom side wall portion, the gas supply path is connected to the device body connection port portion from the lower space outside the device body. In order to secure the connection space, the device must be installed in a state of being considerably lifted with respect to the device installation surface. The body height (that is, the height from the body installation surface to the top of the body) becomes considerably high, which means that, for example, the installation space such as the inside of an existing building or the lower space of an existing drying furnace There was a problem that it was difficult to install.

この実情に鑑み、本発明の主たる課題は、合理的な改良をもって上記問題を効果的に解消する点にある。   In view of this situation, the main problem of the present invention is to effectively solve the above problems with a rational improvement.

〔1〕本発明の第1特徴構成は、蓄熱式ガス処理器に係り、その特徴は、
蓄熱材を収容した複数の蓄熱室と、被処理ガスを燃焼させる燃焼手段を備えた燃焼室と、前記蓄熱室の各々について蓄熱室を介して前記燃焼室に導入される被処理ガス及び燃焼室から蓄熱室を介して導出される処理済ガスを通過させる複数の給排室とを器体内部に形成し、
前記複数の蓄熱室を器体内部の上下中間部において横方向に並べて、各蓄熱室の上端又は下端のうちの一端を前記燃焼室に連通させ、且つ、各蓄熱室の他端を前記給排室の各々に個別に連通させる構造にするとともに、
前記給排室の各々について給排室を介して器体外部から前記燃焼室に被処理ガスを導入する被処理ガス導入状態と給排室を介して器体外部に処理済ガスを導出する処理済ガス導出状態とに交互的に切換可能な複数のガス給排路の各々に対する器体接続口部を形成してある蓄熱式ガス処理器であって、
前記複数の器体接続口部を、器体横外方空間から前記ガス供給路を接続可能な形態で横側壁部に形成してある点にある。
[1] A first characteristic configuration of the present invention relates to a regenerative gas processor,
A plurality of heat storage chambers containing a heat storage material, a combustion chamber provided with combustion means for combusting a gas to be processed, and a gas to be processed and a combustion chamber introduced into the combustion chamber via the heat storage chamber for each of the heat storage chambers A plurality of supply and discharge chambers through which the processed gas derived from the heat storage chamber is passed are formed inside the container body,
The plurality of heat storage chambers are arranged in the horizontal direction at the upper and lower intermediate portions inside the body, and one end of each heat storage chamber is communicated with the combustion chamber, and the other end of each heat storage chamber is connected to the supply / discharge In addition to a structure that allows each room to communicate individually,
For each of the supply / exhaust chambers, a process gas introduction state in which the process gas is introduced into the combustion chamber from the outside of the container through the supply / discharge chamber, and a process for deriving the processed gas to the outside of the container through the supply / discharge chamber A regenerative gas processing device in which a vessel connection port portion is formed for each of a plurality of gas supply / exhaust passages that can be switched alternately to a spent gas derivation state,
The plurality of vessel connection ports are formed in the side wall portion in a form in which the gas supply path can be connected from the vessel lateral outer space.

つまり、上記第1特徴構成によれば、ガス供給路を器体横外方空間から器体接続口部に接続することができるから、先述の従来構造のように器体設置面に対して相当浮かせた状態で器体を設置しなくとも、器体接続口部に対するガス供給路の接続空間を確保することができる。   That is, according to the first characteristic configuration, the gas supply path can be connected from the lateral lateral space to the instrument connection port, which is equivalent to the instrument installation surface as in the conventional structure described above. Even if the container is not installed in a floating state, the connection space of the gas supply path to the container connection port can be secured.

したがって、先述の従来構造に比べて実質的な器体高さを小さくすることができて、既存の建物内部や既存の乾燥炉の下部空間などの設置スペースに対して設置し易いものとすることができる。   Therefore, the substantial body height can be reduced as compared with the above-mentioned conventional structure, and it should be easy to install in an installation space such as an existing building interior or a lower space of an existing drying furnace. it can.

〔2〕本発明の第2特徴構成は、第1特徴構成の実施に好適な実施形態を特定するものであり、その特徴は、
前記複数の器体接続口部を、複数の横側壁部のうちの一つの横側壁部に集中的に形成してある点にある。
[2] The second characteristic configuration of the present invention specifies an embodiment suitable for the implementation of the first characteristic configuration.
The plurality of vessel connection ports are intensively formed on one of the plurality of lateral side walls.

つまり、上記第2特徴構成によれば、例えば、複数の器体接続口部を複数の横側壁部に分散させて形成するのに比べて、実質的な平面視面積(つまり、ガス給排路の接続空間を含めた平面視面積)を小さくすることができ、これにより、前述の設置スペースに対して一層設置し易いものとすることができる。   In other words, according to the second feature configuration, for example, compared to the case where a plurality of body connection ports are dispersed and formed on a plurality of lateral side walls, a substantial plan view area (that is, a gas supply / discharge path). (Planar view area including the connection space) can be reduced, which makes it easier to install in the installation space.

〔3〕本発明の第3特徴構成は、第2特徴構成の実施に好適な実施形態を特定するものであり、その特徴は、
前記複数の器体接続口部を集中的に形成した横側壁部から離れた前記給排室とそれに対する器体接続口部とを、前記横側壁部に隣接する前記給排室を貫通する連絡風路を介して連通させる構成にしてある点にある。
[3] The third characteristic configuration of the present invention specifies an embodiment suitable for the implementation of the second characteristic configuration.
The supply / exhaust chamber separated from the lateral side wall portion in which the plurality of device body connection ports are formed in a concentrated manner and the body connection port portion corresponding thereto are communicated through the supply / discharge chamber adjacent to the side wall portion. It is in the point which is set as the structure connected through an air path.

つまり、前記複数の器体接続口部を、複数の横側壁部のうちの一つの横側壁部に集中的に形成する構造を採ることに対し、例えば、横側壁部から離れた給排室とそれに対する器体接続口部とを横側壁部に隣接する給排室の外方(つまり、器体内部における給排室の上方、下方、横方)に設けた連絡風路を介して連通させる場合では、その連絡風路の周囲に活用し難い空間が生じてしまう。   That is, in contrast to adopting a structure in which the plurality of container connection ports are formed intensively on one of the plurality of lateral side walls, for example, a supply / discharge chamber separated from the lateral side wall The device body connection port portion is communicated with a communication air passage provided outside the supply / discharge chamber adjacent to the lateral side wall portion (that is, above, below, and laterally of the supply / discharge chamber inside the device body). In some cases, an unusable space is created around the communication air passage.

これに対し、横側壁部から離れた給排室とそれに対する器体接続口部とを横側壁部に隣接する給排室を貫通する連絡風路を介して連通させる上記第3特徴構成であれば、その連絡風路の周囲空間を横側壁部に隣接する給排室の内部空間として効果的に活用することができる。   On the other hand, in the third characteristic configuration, the supply / exhaust chamber separated from the lateral side wall portion and the body connection port portion corresponding to the supply / exhaust chamber communicate with each other via a communication air passage penetrating the supply / exhaust chamber adjacent to the lateral side wall portion. For example, the space around the communication air passage can be effectively used as the internal space of the supply / discharge chamber adjacent to the lateral side wall.

したがって、複数の横側壁部のうちの一つの横側壁部に集中的に形成する構造を採りながらも、器体の少型化を効果的に図ることができて、前述の設置スペースに対して一層設置し易いものとすることができる。   Therefore, while adopting a structure in which one of the plurality of lateral side wall portions is intensively formed, it is possible to effectively reduce the size of the vessel and to reduce the installation space described above. It can be made easier to install.

〔4〕本発明の第4特徴構成は、第3特徴構成の実施に好適な実施形態を特定するものであり、その特徴は、
前記連絡風路を、前記横側壁部に隣接する給排室の内部における前記蓄熱室とは反対側端に配置してある点にある。
[4] The fourth characteristic configuration of the present invention specifies an embodiment suitable for the implementation of the third characteristic configuration.
The communication air passage is located at the end opposite to the heat storage chamber inside the supply / discharge chamber adjacent to the lateral side wall.

つまり、上記第4特徴構成であれば、例えば、前記連絡風路を前記横側壁部に隣接する給排室の内部における蓄熱室側に配置する場合に比べ、給排室の内部における蓄熱室側の空間を広く確保することができるから、蓄熱室内の蓄熱材への通風面積を極力広く採ることができて、熱効率を効果的に向上させるができる。   That is, if it is the above-mentioned 4th characteristic composition, for example, compared with the case where the above-mentioned communication air way is arranged in the heat storage room side in the inside of the supply and discharge room adjacent to the above-mentioned side wall part, the heat storage room side inside the supply and discharge room Since a large space can be secured, the ventilation area to the heat storage material in the heat storage chamber can be taken as wide as possible, and the thermal efficiency can be effectively improved.

なお、第4特徴構成を実施するのに(図3,図4参照)、前記連絡風路10の蓄熱室側面10aを、前記横側壁部9に隣接する給排室6Aの内部における平面視中央側が連絡風路直交方向における平面視外側よりも前記蓄熱室3とは反対側に位置する形態に構成してもよい。In order to implement the fourth characteristic configuration (see FIGS. 3 and 4), the heat storage chamber side surface 10a of the communication air passage 10 is centered in plan view inside the supply / discharge chamber 6A adjacent to the lateral side wall portion 9. You may comprise in the form which a side is located in the opposite side to the said thermal storage chamber 3 rather than the planar view outer side in a connection air path orthogonal direction.

つまり、この構成によれば、前記連絡風路10を前記横側壁部に隣接する給排室6Aの内部における前記蓄熱室とは反対側端に配置する構造を採ることに対し、その連絡風路10の蓄熱室側面10a(すなわち、給排室6Aの連絡風路設置部分における蓄熱室とは反対側面)をもって、器体接続口部8から給排室6Aを通過して蓄熱室へ至る被処理ガス、及び、蓄熱室から給排室6Aを通過して器体接続口部に至る処理済ガスの給排室6A内の通過を案内する形態で給排室6A内のガス通過抵抗を効果的に低減することができ、これにより、処理効率の向上や省エネルギ化を効果的に達成することができる。 That is, according to this configuration , the communication air passage 10 is arranged at the end opposite to the heat storage chamber 3 in the supply / exhaust chamber 6A adjacent to the lateral side wall portion 9 , whereas the communication is performed. regenerator side 10a of the air passage 10 (i.e., the regenerator 3 in contact air passage installed part of Kyuhaishitsu 6A opposite sides) with a regenerator 3 through the supply and discharge chamber 6A from the device body connection opening 8 The supply gas in the supply / discharge chamber 6A is guided in such a manner that the gas to be processed and the processed gas passing from the heat storage chamber 3 through the supply / discharge chamber 6A to the body connection port 8 are guided in the supply / discharge chamber 6A . The gas passage resistance can be effectively reduced, thereby improving the processing efficiency and saving energy effectively.

〕本発明の第特徴構成は、蓄熱式ガス処理設備に係り、その特徴は、
前記第1〜第特徴構成のいずれかに記載の蓄熱式ガス処理器を用いた蓄熱式ガス処理設備であって、
前記ガス給排路の各々を前記被処理ガス導入状態と前記処理済ガス導出状態とに交互的に切り換える切換装置を器体外部に設け、
前記切換装置を、前記複数のガス給排路に対し個別に連通される複数の給排口を有する分配器と、ガス供給路から前記ガス給排路に導入する被処理ガスを通過させる前記給排口とガス給排路からガス排出路に導出する処理済ガスを通過させる給排口との両方が存在する状態を保ちながら、前記分配器に対する摺接状態での横軸芯周り又は斜め軸芯周りの回転により各給排口を被処理ガス通過状態と処理済ガス通過状態とに交互的に切り換える切換弁体とから構成するとともに、
前記蓄熱式ガス処理器の前記器体接続口部それぞれに対して前記ガス給排路それぞれの一端を個別に接続し、且つ、前記切換装置における前記給排口それぞれに対してガス給排路それぞれの他端を個別に連通させる構成にしてある点にある。
[ 5 ] A fifth characteristic configuration of the present invention relates to a regenerative gas processing facility,
A regenerative gas processing facility using the regenerative gas processor according to any one of the first to fourth characteristic configurations,
A switching device for alternately switching each of the gas supply / exhaust passages between the treated gas introduction state and the treated gas derivation state is provided outside the container body,
The switching device includes a distributor having a plurality of supply / exhaust ports individually connected to the plurality of gas supply / exhaust passages, and the supply gas that passes the gas to be treated introduced from the gas supply passage to the gas supply / exhaust passage. While maintaining the state where both the exhaust port and the supply / exhaust port through which the treated gas led out from the gas supply / exhaust passage passes, the horizontal axis around the horizontal axis or the oblique axis in the sliding contact state with respect to the distributor While comprising a switching valve body that alternately switches between the supply gas exhaust port and the processed gas passage state by rotation around the core,
One end of each of the gas supply / discharge paths is individually connected to each of the body connection ports of the regenerative gas processor, and each of the gas supply / discharge paths is connected to each of the supply / discharge ports in the switching device. It is in the point which is made the structure which connects the other end of each separately.

つまり、上記第特徴構成によれば、前記複数のガス給排路を前記被処理ガス導入状態と前記処理済ガス導出状態とに交互的に切り換える切換装置を器体外部に設けるのに対し、切換装置の前記切換弁体を横軸芯周り又は斜め軸芯周りで回転させる構成にしてあるから、例えば、切換弁体を縦軸芯周りで回転させる構成にするのに比べ、切換装置の高さを低くすることができ、これにより、蓄熱式ガス処理器と切換装置とを含めた設備全体の高さを効果的に低くすることができる。 In other words, according to the fifth feature configuration, a switching device that alternately switches the plurality of gas supply / exhaust passages between the treated gas introduction state and the treated gas derivation state is provided outside the body. Since the switching valve body of the switching device is configured to rotate around the horizontal axis or the oblique axis, for example, the switching device is more expensive than the configuration of rotating the switching valve body about the vertical axis. Thus, the height of the entire facility including the regenerative gas processor and the switching device can be effectively reduced.

図1、図2、図6は、蓄熱式ガス処理設備を示し、T1は設備横方部において設備設置面(器体設置面)L上に載置した略箱型形状の蓄熱式ガス処理器であり、この蓄熱式ガス処理器T1は、平面視で並列配置の複数室(本例では、8室)の蓄熱室3を仕切壁2により器体内部の上下中間部において横方向(詳しくは、水平面方向又は略水平面方向)に並べた状態で仕切形成し、それら蓄熱室3の各々に蓄熱材4aの通気性充填層4を収容するとともに、各蓄熱室3の上端を器体内部の上部に形成した燃焼室5に開口連通させ、且つ、各蓄熱室3の下端を仕切壁7により器体内部の下部において横方向(詳しくは、水平面方向又は略水平面方向)に並べた状態で仕切形成した平面視で並列配置の複数室(本例では、8室)の第1給排室6に対し個別に開口連通させてある。   1, 2, and 6 show a regenerative gas processing facility, and T <b> 1 is a substantially box-shaped regenerative gas processing device placed on a facility installation surface (container installation surface) L in a lateral part of the facility. In this heat storage type gas processing device T1, a plurality of chambers (in this example, eight chambers) arranged in parallel in a plan view are arranged in the horizontal direction (particularly in the upper and lower intermediate portions inside the vessel body by the partition wall 2). And partitioning in a state of being arranged in a horizontal plane direction or a substantially horizontal plane direction), the breathable packed layer 4 of the heat storage material 4a is accommodated in each of the heat storage chambers 3, and the upper end of each heat storage chamber 3 is the upper part inside the vessel body A partition is formed in a state in which the lower end of each heat storage chamber 3 is arranged in a horizontal direction (specifically, in a horizontal plane direction or a substantially horizontal plane direction) at the lower part inside the container body by a partition wall 7. The first supply / exhaust chamber 6 of a plurality of chambers (in this example, eight chambers) arranged in parallel in a plan view They are allowed individually communicated open communication.

5aは、被処理ガスGを燃焼させる燃焼手段として燃焼室5の天井部に配設したバーナーである。   5a is a burner disposed on the ceiling of the combustion chamber 5 as a combustion means for burning the gas G to be treated.

前記蓄熱式ガス処理器T1の横側壁部9には、第1給排室6の各々について第1給排室6を介して器体外部から燃焼室5に被処理ガスG(例えば、有機溶剤を含む塗装ブースからの排出空気)を導入する被処理ガス導入状態と、第1給排室6を介して器体外部に処理済ガスG′を導出する処理済ガス導出状態とに交互的に切換可能な複数本(本例では、8本)のガス給排路11の各々に対する複数個(本例では、8個)の器体接続口部8を、器体横外方空間からガス給排路11を接続可能な形態で形成してあり、この器体接続口部8は、器体内部において第1給排室6に対し連通させてある。   In the side wall portion 9 of the regenerative gas processor T1, the gas to be treated G (for example, organic solvent) is supplied from the outside of the container to the combustion chamber 5 via the first supply / discharge chamber 6 for each of the first supply / discharge chambers 6. Alternately to the treated gas introduction state in which the exhaust air from the painting booth including the gas is introduced and the treated gas lead-out state in which the treated gas G ′ is led out to the outside of the container through the first supply / exhaust chamber 6. A plurality of (eight in this example) device connection ports 8 for each of a plurality of switchable (eight in this example) gas supply / discharge passages 11 are supplied from the lateral space outside the device body. The drain passage 11 is formed in a connectable form, and the container connection port 8 is communicated with the first supply / discharge chamber 6 inside the container.

つまり、この蓄熱式ガス処理器T1は、ガス給排路11の各々に対する器体接続口部8を器体横外方空間からガス給排路11を接続可能な形態で横側壁部9に形成することで、器体接続口部8に対するガス供給路11の接続空間を器体横外方空間に確保する。   That is, in this heat storage type gas processor T1, the body connection port 8 for each of the gas supply / discharge passages 11 is formed in the side wall portion 9 in such a form that the gas supply / discharge passage 11 can be connected from the lateral lateral space of the body. By doing so, the connection space of the gas supply path 11 with respect to the container connection port part 8 is ensured in the container body outer space.

T2は、ガス給排路11の各々を被処理ガス導入状態と処理済ガス導出状態とに交互的に切り換える切換装置であり、この切換装置T2は、蓄熱式ガス処理器T1の横方において設備設置面L上に載置してある。   T2 is a switching device that alternately switches each of the gas supply / exhaust passages 11 between a treated gas introduction state and a treated gas lead-out state, and this switching device T2 is installed on the side of the heat storage gas processor T1. It is placed on the installation surface L.

そして、ガス給排路11それぞれの一端を蓄熱式ガス処理器T1の器体接続口部8それぞれに対して器体外部横方空間から個別に接続するとともに、ガス給排路11それぞれの他端を切換装置T2に対して接続する構成にしてある。   Then, one end of each gas supply / discharge path 11 is individually connected to each of the body connection port portions 8 of the regenerative gas processor T1 from the lateral space outside the body, and the other end of each gas supply / discharge path 11 Are connected to the switching device T2.

前記器体接続口部8は、複数(本例では4つ)の横側壁部9のうちの一つの横側壁部9に集中的に形成して、ガス給排路11を接続することに対し蓄熱式ガス処理器T1の実質的な平面視面積(つまり、ガス給排路11の接続空間を含めた蓄熱式ガス処理器T1の平面視面積)を小さくする構成にしてあり、具体的には、切換装置T2側の横側壁部9における第1給排室6に対応した下部に横一文字状に並べた状態で形成してある。   The vessel connection port portion 8 is formed intensively on one of the plurality (four in this example) of the side wall portions 9 to connect the gas supply / discharge passage 11. The substantial plan view area of the heat storage type gas processor T1 (that is, the plan view area of the heat storage type gas processor T1 including the connection space of the gas supply / exhaust passage 11) is reduced. Specifically, The horizontal side wall portion 9 on the switching device T2 side is formed in a state of being arranged in a single horizontal character at the lower portion corresponding to the first supply / discharge chamber 6.

図3〜図6に示すように、切換装置T2側の横側壁部9に隣接する4室の第1給排室6(隣接第1給排室6A)に対しては、これに対応する器体接続口部8の内側開口8aを開口連通させる構成にするとともに、切換装置T2側の横側壁部9から離れた4室の第1給排室6(非隣接第1給排室6B)に対しては、これに対応する器体接続口部8の内側開口8aを、隣接第1給排室6Aを貫通する金属製の連絡ダクト10(連絡風路の一例)を介して連通させる構成にしてあり、連絡ダクト10の周囲空間を隣接第1給排室6Aの内部空間として活用する構成にしてある。   As shown in FIGS. 3 to 6, for the four first supply / discharge chambers 6 (adjacent first supply / discharge chambers 6 </ b> A) adjacent to the lateral wall portion 9 on the switching device T <b> 2 side, a corresponding device is provided. The inner opening 8a of the body connection port 8 is configured to communicate with the opening, and the four first supply / discharge chambers 6 (non-adjacent first supply / discharge chambers 6B) separated from the lateral side wall 9 on the switching device T2 side are provided. On the other hand, the inner opening 8a of the corresponding container connection port 8 is configured to communicate with each other via a metal communication duct 10 (an example of a communication air passage) that penetrates the adjacent first supply / discharge chamber 6A. The space around the communication duct 10 is used as the internal space of the adjacent first supply / discharge chamber 6A.

前記連絡ダクト10は、隣接第1給排室6Aの平面視器体中央側の壁面に隣接する状態で隣接第1給排室6Aの床面(蓄熱室3とは反対側端の一例)に配置してあり、これにより、隣接第1給排室6Aの天井面(つまり、蓄熱室3に対する開口面)が連絡ダクト10により部分的に閉塞されるのを抑止して、隣接第1給排室6Aと蓄熱室3との連通面積を確保する。   The connecting duct 10 is adjacent to the wall surface of the adjacent first supply / exhaust chamber 6A on the center side of the planar view body, on the floor surface of the adjacent first supply / exhaust chamber 6A (an example of the end opposite to the heat storage chamber 3). Thus, the ceiling surface of the adjacent first supply / discharge chamber 6A (that is, the opening surface with respect to the heat storage chamber 3) is prevented from being partially blocked by the communication duct 10, and the adjacent first supply / discharge chamber is suppressed. A communication area between the chamber 6A and the heat storage chamber 3 is secured.

また、連絡ダクト10の天井面10a(蓄熱室側面の一例)は、隣接第1給排室6Aの内部における平面視中央側が連絡ダクト直交方向における平面視外側よりも蓄熱室3とは反対側に位置する形態、詳しくは、平面視中央側ほど下方側に位置する傾斜面形状(略言すれば、片流れ天井形状)に形成してあり、この天井面10aの傾斜面に沿って隣接第1給排室6Aと蓄熱室3との間でのガス通風を案内する形態で、隣接第1給排室6A内のガス通過抵抗を効果的に低減する。   Further, the ceiling surface 10a (an example of the side surface of the heat storage chamber) of the communication duct 10 is such that the center side in plan view inside the adjacent first supply / discharge chamber 6A is on the opposite side of the heat storage chamber 3 from the outside in plan view in the direction perpendicular to the communication duct. More specifically, it is formed in an inclined surface shape (in short, a single-flow ceiling shape) located closer to the center side in plan view, and the adjacent first first supply along the inclined surface of the ceiling surface 10a. In the form of guiding the gas ventilation between the exhaust chamber 6A and the heat storage chamber 3, the gas passage resistance in the adjacent first supply / exhaust chamber 6A is effectively reduced.

なお、隣接第1給排室6Aに対する器体接続口部8は、外側開口8a(すなわち、横側壁部9の外側面の開口)がガス供給路11に対応した円形状で、且つ、内側開口8b(すなわち、横側壁部9の内側面の開口)が外側開口8aと略同一形状の横軸芯角柱状の筒形状に形成してあり、一方、非隣接第1給排室6Bに対する器体接続口部8は、外側開口8aがガス給排路11に対応した円形状で、且つ、内側開口8bが連絡ダクト10に対応した形状の略横軸芯角錐台状の筒形状に形成してある。 The body connection port 8 for the adjacent first supply / discharge chamber 6A has an outer opening 8a (that is, an opening on the outer surface of the lateral side wall 9) having a circular shape corresponding to the gas supply path 11, and an inner opening. 8b (that is, the opening on the inner side surface of the lateral side wall portion 9) is formed in a cylindrical shape of a horizontal axis prismatic shape substantially the same shape as the outer opening 8a , while the container for the non-adjacent first supply / discharge chamber 6B The connection port portion 8 is formed in a cylindrical shape having a substantially horizontal axis pyramid shape in which the outer opening 8 a has a circular shape corresponding to the gas supply / discharge passage 11 and the inner opening 8 b has a shape corresponding to the connecting duct 10. is there.

前記切換装置T2は、複数のガス給排路11に対し個別に連通される複数の給排口14Aを有する分配器12と、ガス供給路45から前記ガス給排路11に導入する被処理ガスGを通過させる給排口14Aとガス給排路11からガス排出路46に導出する処理済ガスG′を通過させる給排口14Aとの両方が存在する状態を保ちながら、分配器12に対する摺接状態での横軸芯周りの回転(詳しくは、水平軸芯又は略水平軸芯周りの回転)により各給排口14Aを被処理ガス通過状態と処理済ガス通過状態とに交互的に切り換える風路切換用の切換弁体15とから構成してある。   The switching device T2 includes a distributor 12 having a plurality of supply / discharge ports 14A individually connected to the plurality of gas supply / discharge passages 11, and a gas to be treated introduced from the gas supply passage 45 into the gas supply / discharge passage 11. While maintaining both the supply / exhaust port 14A through which the gas G passes and the supply / exhaust port 14A through which the processed gas G ′ led out from the gas supply / exhaust channel 11 to the gas exhaust channel 46 passes, the sliding to the distributor 12 is maintained. Each supply / exhaust port 14A is alternately switched between the gas to be processed state and the gas passage state to be processed by rotation around the horizontal axis in contact state (specifically, rotation around the horizontal axis or substantially horizontal axis). It is comprised from the switching valve body 15 for an air path switching.

具体的には、切換装置T2は、図7〜図10に示す如く、処理済ガスG′を受け入れる円筒状の気室器16を内部の右横方(すなわち、蓄熱式ガス処理器T1とは反対側)に備えた弁体器17と、その弁体器17における気室器16の左横方(すなわち、蓄熱式ガス処理器T1側)に内装された前記切換弁体15と、側面視で環状配置の8個の第2給排室14を仕切壁13により内部に形成した側面視略円筒状の前記分配器12とからなり、設備設置面Lに支持された正面視略L字状の設置架台18に分配器12を固定的に取り付けるとともに、弁体器17を分配器12の右横方に同心状に配置して分配器12に対し固定的に連結し、これにより、左横方から‘分配器12−切換弁体15−気室器16’の順で同芯状に配置する構成にしてある。   Specifically, as shown in FIGS. 7 to 10, the switching device T2 has a cylindrical air chamber 16 that receives the treated gas G ′ and a right side of the inside (that is, the regenerative gas processor T1). A valve body 17 provided on the opposite side), the switching valve body 15 provided on the left side of the air chamber 16 in the valve body 17 (that is, the heat storage gas processor T1 side), and a side view. And the second distributor 14 having an annular arrangement formed therein by the partition wall 13 and having a substantially cylindrical shape in a side view, and having a substantially L shape in a front view supported by the equipment installation surface L. The distributor 12 is fixedly attached to the installation base 18 and the valve body 17 is concentrically arranged on the right side of the distributor 12 and fixedly connected to the distributor 12. From the direction, it is arranged in the order of 'distributor 12-switching valve body 15-air chamber 16' concentrically. .

前記弁体器17の天板(換言すれば、左側板)を兼ねる分配器12の底板(換言すれば、右側板)12aには、8個の扇状の給排口14Aを各第2給排室14に対し個別に対応位置させた環状配置(すなわち、後述する切換弁体15の回転方向に並ぶ配置)で形成し、その底板12aの右側面には、外周部19aと内周部19bと8本の放射状部19cとからなって給排口14Aを個々に囲む形態の分配器側シール部材19を付設してある。   On the bottom plate (in other words, the right side plate) 12a of the distributor 12 that also serves as the top plate (in other words, the left side plate) of the valve body 17, eight fan-shaped supply / exhaust ports 14A are provided for each second supply / discharge port. It is formed in an annular arrangement (that is, an arrangement aligned in the rotation direction of the switching valve body 15 described later) individually corresponding to the chamber 14, and an outer peripheral portion 19a and an inner peripheral portion 19b are formed on the right side surface of the bottom plate 12a. A distributor-side seal member 19 is provided which is composed of eight radial portions 19c and individually surrounds the supply / discharge port 14A.

14aは、各給排口14Aを半径方向で複数(本例では3個)に分割する形態で周方向に亘らせた環状補強部である。   Reference numeral 14a denotes an annular reinforcing portion that extends in the circumferential direction in a form in which each supply / exhaust port 14A is divided into a plurality (three in this example) in the radial direction.

弁体器17に内装する切換弁体15は、図9、図10に示すように、円板状の弁天板(換言すれば、左側板)22とそれよりもやや小径の円板状の弁底板(換言すれば、右側板)23と弁周壁21と横姿勢の回転軸Xを構成する筒状回転軸24とを備える略横向き円錐台形状に形成してあり、弁天板22を分配器12の底板12aに対して摺接(厳密には分配器側シール部材19に対して摺接)させ、かつ、弁底板23を気室器16の器内空間17A側の開口縁部(詳しくは、後述する摺接部53の左端開口縁部)に対して摺接(厳密には、開口縁部に装備した環状の気室器側シール部材25に対して摺接)させる形態で、弁体器17内において横軸心P周りで図中矢印Rで示す方向に回転させる。   As shown in FIGS. 9 and 10, the switching valve body 15 provided in the valve body 17 includes a disc-shaped valve top plate (in other words, a left side plate) 22 and a disc-shaped valve having a slightly smaller diameter. The bottom plate (in other words, the right side plate) 23, the valve peripheral wall 21, and the cylindrical rotary shaft 24 that forms the horizontal rotation shaft X are formed in a substantially horizontal truncated cone shape. The bottom plate 12a is slidably contacted (strictly, slidably contacted with the distributor-side seal member 19), and the valve bottom plate 23 is opened on the inner space 17A side of the air chamber 16 (more specifically, In the form of sliding contact (strictly speaking, sliding contact with the annular air chamber side seal member 25 provided at the opening edge) with respect to a left end opening edge of the sliding contact portion 53 described later. 17 is rotated around the horizontal axis P in the direction indicated by the arrow R in the figure.

前記切換弁体15の回転軸Xは、分配器12を貫通する状態で設置架台18に支持される第1連結回転軸26を筒状回転軸24の先端(換言すれば、左端)に対し着脱自在に連結するとともに、気室器16及びそれの内部右横方に形成のパージ用チャンバ20を貫通する状態で気室器16に支持される第2連結回転軸27を、筒状回転軸24の基端(換言すれば、右端)に対し着脱自在に連結して構成してある。   The rotating shaft X of the switching valve body 15 is attached to and detached from the tip of the cylindrical rotating shaft 24 (in other words, the left end) with respect to the first connecting rotating shaft 26 supported by the installation base 18 in a state of penetrating the distributor 12. The second connecting rotary shaft 27 supported by the air chamber 16 in a state of being freely connected and passing through the air chamber 16 and the purge chamber 20 formed on the right side of the inside of the air chamber 16 is connected to the cylindrical rotary shaft 24. The base end (in other words, the right end) is detachably connected.

詳しくは、分配器12と設置架台18との間において筒状回転軸24の先端に対しボルトやナット等の締結手段により第1連結回転軸26をフランジ接合するとともに、気室器16内部の左方部分において筒状回転軸24の基端に対しボルトやナット等の締結手段により第2連結回転軸27をフランジ接合して構成してある。   Specifically, between the distributor 12 and the installation base 18, the first connecting rotary shaft 26 is flange-bonded to the tip of the cylindrical rotary shaft 24 by fastening means such as bolts and nuts, and the left inside the air chamber 16 is left. The second connecting rotary shaft 27 is flange-joined to the base end of the cylindrical rotary shaft 24 by a fastening means such as a bolt or a nut at the side portion.

また、筒状回転軸24の基端面には、それの内部空間に連通する第1パージ用連通口24aを形成するとともに、第2連結回転軸27の先端面には、それの内部空間に連通する第3パージ用連通口27aを形成してあり、これにより、筒状回転軸24と第2連結回転軸27との連結状態において、それらの内部空間どうしが連通接続される構成にしてある。   Further, the base end surface of the cylindrical rotating shaft 24 is formed with a first purge communication port 24a communicating with the inner space thereof, and the distal end surface of the second connecting rotating shaft 27 communicates with the inner space thereof. The third purge communication port 27a is formed, so that the internal space of the cylindrical rotation shaft 24 and the second connection rotation shaft 27 are connected in communication with each other.

さらに、第1連結回転軸26は、それの軸心P方向への動きを許す第1軸受28を介して設置架台18により支持させるとともに、第2連結回転軸27は、それの軸芯P方向への滑りを許し、かつ、気室器16及びパージ用チャンバ20との隙間を通じて処理済ガスG′が外部に漏洩することを防止するためのシール部材を備えた第2軸受29及び第3軸受30を介して気室器16により支持させており、これにより、切換弁体15の回転軸Xの軸心P方向への動きを自在に構成してある。   Further, the first coupling rotary shaft 26 is supported by the installation base 18 via a first bearing 28 that allows movement in the axis P direction thereof, and the second coupling rotary shaft 27 is supported in the direction of the axis P thereof. The second bearing 29 and the third bearing provided with seal members that allow the treated gas G ′ to leak outside through the gap between the air chamber 16 and the purge chamber 20. 30 and is supported by the air chamber 16 so that the switching valve body 15 can freely move in the direction of the axis P of the rotation axis X.

前記切換弁体15の弁天板22には、切換弁体15の回転に伴い分配器12の側の給排口14Aに対して順次に対向連通させる被処理ガス用供給口31とパージ用口32と処理済ガス用排出口33とをその順で切換弁体15の回転上手側から並ぶ環状配置で、かつ、分配器12の側における同一の給排口14A(厳密には同一の給排口14Aに対する分配器側シール部材19の囲い領域)に対して同時に対向連通することがない配置で形成してある。   In the valve top plate 22 of the switching valve body 15, a gas supply port 31 and a purge port 32 that are sequentially opposed to and communicated with the supply / discharge port 14 A on the distributor 12 side as the switching valve body 15 rotates. And the treated gas discharge port 33 are arranged in this order from the upper rotation side of the switching valve body 15, and the same supply / discharge port 14A (strictly, the same supply / discharge port on the distributor 12 side). 14A is formed so as not to communicate with each other at the same time (enclosed region of the distributor-side seal member 19 with respect to 14A).

また、弁底壁23には、気室器16内に対し連通させる気室器用の連通口34を形成するとともに、弁周壁21には、弁体器17内における切換弁体15及び気室器16周りの器内空間17Aに対し連通させる弁体器用の連通口35を形成してある。   The valve bottom wall 23 is formed with a communication port 34 for the air chamber to communicate with the inside of the air chamber 16, and the switching valve body 15 and the air chamber in the valve body 17 are formed on the valve peripheral wall 21. A communication port 35 for a valve body that is communicated with the internal space 17A around 16 is formed.

さらに、筒状回転軸24には、その内部空間を後述するパージ用室38に対し連通させる第2パージ用連通口24bを形成するとともに、筒状回転軸24に対し内部空間どうしが連通する状態で連結される第2連結回転軸27には、その内部空間をパージ用チャンバ20に対し連通させる第4パージ用連通口27bを形成してあり、これにより、第2パージ用連通口24b、筒状回転軸24の内部空間、第2連結回転軸27の内部空間、第4パージ用連通口27bを介して、パージ用室38とパージ用チャンバ20とを連通させる構成にしてある。   Further, the cylindrical rotary shaft 24 is formed with a second purge communication port 24b that communicates the internal space with a purge chamber 38 to be described later, and the internal space communicates with the cylindrical rotary shaft 24. A second purge communication port 27b is formed in the second connection rotary shaft 27 connected to the purge chamber 20. The fourth purge communication port 27b communicates the internal space with the purge chamber 20. The purge chamber 38 and the purge chamber 20 are communicated with each other via the internal space of the cylindrical rotary shaft 24, the internal space of the second connection rotary shaft 27, and the fourth purge communication port 27b.

15aは、被処理ガス用供給口31、処理済ガス用排出口33の夫々を半径方向で複数(本例では3個)に分割する形態で周方向に亘らせた環状補強部である。   Reference numeral 15a denotes an annular reinforcing portion that extends in the circumferential direction in such a manner that each of the gas supply port 31 and the gas discharge port 33 to be processed is divided into a plurality (three in this example) in the radial direction.

切換弁体15の内部には、弁周壁21に形成の弁体器用連通口35と弁天板22に形成の被処理ガス用供給口31とを室出入口とする供給室36と、弁底壁23に形成の気室器用連通口34と弁天板22に形成の処理済ガス用排出口33とを室出入口とする排出室37とを、横仕切壁39、第1天板側横仕切壁40、及び、螺旋状の仕切中床41により区画形成するとともに、筒状回転軸24に形成の第1パージ用連通口24aと弁天板22に形成のパージ用口32とを室出入口とするパージ用室38を、第1天板側横仕切壁40の隣接箇所に形成した仕切中底42と第2天板側横仕切壁43とにより区画形成してある。   Inside the switching valve body 15 are a supply chamber 36 having a valve body communication port 35 formed on the valve peripheral wall 21 and a gas supply port 31 formed on the valve top plate 22 as a chamber inlet and outlet, and a valve bottom wall 23. A discharge chamber 37 having a communication port 34 for the air chamber formed in the above and a discharge port 33 for the processed gas formed in the valve top plate 22 as a chamber inlet / outlet, a horizontal partition wall 39, a first top plate side horizontal partition wall 40, A purge chamber that is partitioned by a spiral partitioning inner floor 41 and has a first purge communication port 24a formed in the cylindrical rotary shaft 24 and a purge port 32 formed in the valve top plate 22 as a chamber inlet / outlet. 38 is partitioned by a partition middle bottom 42 and a second top plate side horizontal partition wall 43 formed at a location adjacent to the first top plate side horizontal partition wall 40.

つまり、螺旋状の仕切中床41を用いて切換弁体15の内部を供給室36と排出室37とに区画することで、弁底壁23の気室器用連通口34の開口面積を広く確保して排出効率を高く確保しながらも弁体横方向長さの短縮化を図ってある。   That is, by dividing the inside of the switching valve body 15 into the supply chamber 36 and the discharge chamber 37 using the spiral partitioning inner floor 41, a wide opening area of the communication port 34 for the air chamber device in the valve bottom wall 23 is secured. Accordingly, the lateral length of the valve body is shortened while ensuring high discharge efficiency.

なお、44は、室内連通用の連通口44aを備えた補強リブ板である。   Reference numeral 44 denotes a reinforcing rib plate provided with a communication port 44a for indoor communication.

そして、この構成において、被処理ガスGを供給するガス供給路45を弁体器17内の器内空間17Aに連通接続し、ファンFにより処理済ガスG′を排出するガス排出路46を弁体器17内における切換弁体15及び気室器16周りの器内空間17Aに連通接続し、処理済ガスG′の一部をガス排出路46から取り出してパージ用ガスG″として供給するパージ用ガス供給路47を気室器16の内部に形成のパージ用チャンバ20に連通接続するとともに、蓄熱式ガス処理器T1の器体接続口部8に各々の一端が接続された8個のガス給排路11の他端を8個の第2給排室14の各々に個別に連通接続してある。   In this configuration, the gas supply path 45 for supplying the gas G to be processed is connected to the internal space 17A in the valve body 17 and the gas discharge path 46 for discharging the processed gas G ′ by the fan F is valved. A purge connected to the switching valve body 15 in the body 17 and the internal space 17A around the air chamber 16, and a part of the treated gas G ′ is taken out from the gas discharge passage 46 and supplied as the purge gas G ″. The gas supply path 47 is connected to the purge chamber 20 formed inside the air chamber 16 and is connected to the body connection port 8 of the regenerative gas processor T1 at each of the eight gases. The other end of the supply / discharge path 11 is individually connected to each of the eight second supply / discharge chambers 14.

つまり、この蓄熱式ガス処理設備では、図7、図15に示すように、ガス供給路45から弁体器17の器内空間17A及び切換弁体15の弁周壁21に形成の弁体器用連通口35を通じて切換弁体15の供給室36に導入される被処理ガスGを、切換弁体15の弁天板22に形成の被処理ガス供給口33、その被処理ガス供給口33に対向連通する分配器12側の給排口14A、その給排口14Aに連通の第2給排室14、その第2給排室14に連通のガス給排路11、そのガス給排路11に連通の器体接続口部8、及び、その器体接続口部8に連通の第1給排室6を通じ、一部の蓄熱室3に通過させて燃焼室5に至らせ、この燃焼室5において被処理ガスG中の汚染物質や悪臭物質などを燃焼により処理する。   That is, in this regenerative gas processing facility, as shown in FIGS. 7 and 15, the valve body communication formed in the internal space 17 </ b> A of the valve body 17 and the valve peripheral wall 21 of the switching valve body 15 from the gas supply path 45. The gas to be processed G introduced into the supply chamber 36 of the switching valve body 15 through the port 35 communicates with the gas supply port 33 to be processed formed in the valve top plate 22 of the switching valve body 15 and the gas supply port 33 to be processed. A supply / discharge port 14A on the distributor 12 side, a second supply / discharge chamber 14 communicating with the supply / discharge port 14A, a gas supply / discharge channel 11 communicating with the second supply / discharge chamber 14, and a gas supply / discharge channel 11 communicated with the gas supply / discharge channel 11 The chamber connection port 8 and the first supply / exhaust chamber 6 communicating with the chamber connection port 8 are passed through a part of the heat storage chamber 3 to reach the combustion chamber 5. Contaminants and malodorous substances in the processing gas G are processed by combustion.

また、処理済ガスG′は、燃焼室5から他の蓄熱室3に通過させて、その蓄熱室3に収容の蓄熱材4aに対し蓄熱を行わせ、その後、その蓄熱室3に連通の第1給排室6、その第1給排室6に連通の器体接続口部8、その器体接続口部8に連通のガス給排路11、その給排路15に連通の第2給排室14、その第2給排室14に連通の給排口14A、及び、その給排口14Aに対向連通する切換弁体15側の処理済ガス用排出口33を通じ、切換弁体15の排出室37へ導くとともに、それに続き、気室器用連通口34及び気室器16を通じて、ガス排出路46へ導出する。   Further, the treated gas G ′ is passed from the combustion chamber 5 to the other heat storage chamber 3 to store heat in the heat storage material 4 a accommodated in the heat storage chamber 3, and thereafter, the first gas communicated with the heat storage chamber 3. 1 supply / discharge chamber 6, an instrument body connection port portion 8 communicating with the first supply / discharge chamber 6, a gas supply / discharge passage 11 communicating with the device body connection port portion 8, and a second supply channel communicating with the supply / discharge passage 15 The switching valve body 15 is connected through the exhaust chamber 14, the supply / exhaust port 14A communicating with the second supply / exhaust chamber 14, and the treated gas discharge port 33 on the switching valve body 15 side facing the supply / exhaust port 14A. In addition to being led to the discharge chamber 37, the gas is led to the gas discharge path 46 through the communication port 34 for the air chamber and the air chamber 16.

さらに、図8、図15に示すように、パージ用ガス供給路47からパージ用チャンバ20に導入されるパージ用ガスG″を、第2連結回転軸27に形成の第3パージ用連通口27a、第2連結回転軸27及び筒状回転軸24の内部空間、切換弁体15の筒状回転軸24に形成の第1パージ用連通口24aを通じ、切換弁体15のパージ用室38へ導くとともに、切換弁体15の弁天板22に形成のパージ用口32、そのパージ用口32に対向連通する分配器12側の給排口14A、その給排口14Aに連通の第2給排室14、その第2給排室14に連通のガス給排路11、そのガス給排路11に連通の器体接続口部8、及び、その器体接続口部8に連通の第1給排室6を通じ、更に他の蓄熱室3に通過させて燃焼室5に至らせ、この燃焼室5においてパージ用ガスG″を燃焼により処理し、処理済ガスG′に合流させる。   Further, as shown in FIGS. 8 and 15, the purge gas G ″ introduced from the purge gas supply passage 47 into the purge chamber 20 is supplied to the third purge communication port 27a formed in the second coupling rotary shaft 27. The internal space of the second connecting rotary shaft 27 and the cylindrical rotary shaft 24 and the first purge communication port 24 a formed in the cylindrical rotary shaft 24 of the switching valve body 15 are led to the purge chamber 38 of the switching valve body 15. A purge port 32 formed in the valve top plate 22 of the switching valve body 15, a supply / discharge port 14 </ b> A on the distributor 12 side that communicates with the purge port 32, and a second supply / discharge chamber connected to the supply / discharge port 14 </ b> A. 14, a gas supply / discharge passage 11 communicating with the second supply / discharge chamber 14, an instrument body connection port portion 8 communicating with the gas supply / discharge passage 11, and a first supply / exhaust passage communicating with the device connection port portion 8. Through the chamber 6, it is further passed through another heat storage chamber 3 to reach the combustion chamber 5, and this combustion chamber 5 Treated with combusting Oite purge gas G ", to merge the treated gas G '.

そして、この処理において切換弁体15を回転させることで、切換弁体15の弁天板22に形成の被処理ガス用供給口31、パージ用口32、処理済ガス用排出口33の各々を対向連通させる分配器12側の給排口14Aを順次に切り換えて、この切り換えにより、被処理ガスGを通過させる蓄熱室3、パージ用ガスG″を通過させる蓄熱室3、処理済ガスG′を通過させる蓄熱室3を順次に切り換える形態で、各蓄熱室3を被処理ガスGの通過状態、パージ用ガスG″の通過状態、処理済ガスG′の通過状態に、その順で順次に切り換え、これにより、処理済ガスG′の通過をもって先に蓄熱した蓄熱材4aにより被処理ガスGを各蓄熱室3の通過過程において予熱する。   Then, by rotating the switching valve body 15 in this process, the gas supply port 31, purge port 32, and processed gas discharge port 33 formed on the valve top plate 22 of the switching valve body 15 are opposed to each other. The supply / exhaust port 14A on the distributor 12 side to be communicated is sequentially switched, and by this switching, the heat storage chamber 3 through which the gas G to be processed passes, the heat storage chamber 3 through which the purge gas G ″ passes, and the processed gas G ′ are changed. In the form of sequentially switching the heat storage chambers 3 to be passed, the respective heat storage chambers 3 are sequentially switched to the passing state of the gas G to be processed, the passing state of the purge gas G ″, and the passing state of the processed gas G ′ in that order. Thus, the gas to be processed G is preheated in the process of passing through each of the heat storage chambers 3 by the heat storage material 4a previously stored with the passage of the processed gas G ′.

また、被処理ガスGの通過後、次に処理済ガスG′を通過させるに先立ち各蓄熱室3にパージ用ガスG″(処理済ガスG′の一部)を通過させるようにし、これにより、蓄熱室3内に残る被処理ガスGを次の処理済ガスG′の通過の前に燃焼室5へ排出して、次にその蓄熱室3を通過する処理済ガスG′に残留被処理ガスGが混入することを防止する。   In addition, after passing the gas to be processed G, the purge gas G ″ (a part of the processed gas G ′) is allowed to pass through each heat storage chamber 3 before passing the processed gas G ′ next. The gas to be processed G remaining in the heat storage chamber 3 is discharged to the combustion chamber 5 before passing the next processed gas G ′, and then the gas to be processed G ′ passing through the heat storage chamber 3 is left to be processed. The gas G is prevented from being mixed.

なお、図6に示すように、蓄熱式ガス処理器T1の8個の器体接続口部8と切換装置T2の8室の第2給排室14とを8個のガス給排路11により個別に接続するのに、隣接第1給排室6A用の4個の器体接続口部8に対し上方側の4室の第2給排室14に接続される上方側のガス給排路11aを個別に接続し、非隣接第1給排室6B用の4個の器体接続口部8に対し下方側の4室の第2給排室14に接続される下方側のガス給排路11bを個別に接続する構成にしてあり、各第1給排室6から各ガス給排路11を介して第2給排室14に至る各風路長さの均一化を図ってある。   In addition, as shown in FIG. 6, eight gas body connection ports 8 of the regenerative gas processor T1 and eight second supply / discharge chambers 14 of the switching device T2 are connected by eight gas supply / discharge channels 11. Upper gas supply / exhaust passages connected to the four second chambers 14 for the adjacent first supply / exhaust chambers 6A to the four body connection ports 8 for the individual connection. 11a are individually connected and the lower gas supply / discharge connected to the four second supply / discharge chambers 14 on the lower side with respect to the four container connection ports 8 for the non-adjacent first supply / discharge chambers 6B. The paths 11b are individually connected, and the lengths of the air paths from the first supply / discharge chambers 6 to the second supply / discharge chambers 14 through the gas supply / discharge paths 11 are made uniform.

前記設置架台18の右側方(詳しくは、弁体器17よりも右側方)には、切換弁体15を回転させる駆動ユニット48を着脱自在に配設してあり、この駆動ユニット48は、切換弁体15の回転軸Xにボルトやナット等の締結手段にて着脱自在に連結(詳しくは、フランジ接合)される連結部としての連結フランジ部49aを備える駆動回転軸49と、押圧片50b及び軸受50aを介して駆動回転軸49を右方から気体や液体の圧力で切換弁体15の回転軸Xに対する接近側(左方側)に押圧支持する切換弁体用付勢手段としてのシリンダ50と、駆動回転軸49とのチェーン接続により駆動回転軸49を回転させる減速機付きモータ51とを、設置架台18に対し着脱自在に取り付けられるフレーム枠52に対し組み付けて構成してある。   A drive unit 48 for rotating the switching valve body 15 is detachably disposed on the right side of the installation base 18 (specifically, on the right side of the valve body 17). A driving rotary shaft 49 including a connecting flange portion 49a as a connecting portion that is detachably connected to the rotating shaft X of the valve body 15 by fastening means such as a bolt or a nut (specifically, flange joint), a pressing piece 50b, A cylinder 50 as a switching valve body urging means for pressing and supporting the driving rotary shaft 49 from the right side to the approaching side (left side) of the switching valve body 15 with respect to the rotation axis X with the pressure of gas or liquid via the bearing 50a. And a motor 51 with a speed reducer that rotates the drive rotary shaft 49 by a chain connection with the drive rotary shaft 49 is assembled to a frame frame 52 that is detachably attached to the installation base 18.

つまり、駆動ユニット48は、駆動回転軸49を介してシリンダ50による押圧力を切換弁体15の回転軸Xに伝達することで、シリンダ50の押圧力が気室器16に対しては非作用の状態で切換弁体15を分配器12に対する遠近方向(本例では、横方向)での変位を自在に分配器12の側へ付勢しながら、減速機付きモータ51による回転力を駆動回転軸49により切換弁体15の回転軸Xに伝達することで、切換弁体15を弁体器17内において横軸芯P周りで図中矢印Rで示す方向に回転させる。   That is, the drive unit 48 transmits the pressing force by the cylinder 50 to the rotating shaft X of the switching valve body 15 via the driving rotating shaft 49, so that the pressing force of the cylinder 50 does not act on the air chamber 16. In this state, the switching valve body 15 is driven and rotated by the motor 51 with a speed reducer while urging the displacement in the perspective direction (in this example, the lateral direction) with respect to the distributor 12 freely toward the distributor 12 side. By transmitting to the rotation axis X of the switching valve body 15 by the shaft 49, the switching valve body 15 is rotated around the horizontal axis P in the valve body 17 in the direction indicated by the arrow R in the figure.

前記気室器16は、左側開口縁部を切換弁体15に対する摺接面とする円筒状の摺接部53とそれの右側の気室器本体54とに分割するとともに、それら摺接部53と気室器本体54とを、気密性と可撓性を備える布製の伸縮風洞55により、摺接部53と気室器本体54との間の環状の隙間を覆う状態(つまり、摺接部53と気室器本体54との間を気密状態又はほぼ気密状態に保持する状態)で連結して構成してある。   The air chamber 16 is divided into a cylindrical sliding contact portion 53 whose left opening edge is a sliding contact surface with respect to the switching valve body 15 and an air chamber main body 54 on the right side thereof, and the sliding contact portion 53. And the air chamber main body 54 are covered with an annular gap between the sliding contact portion 53 and the air chamber main body 54 by a cloth-made telescopic wind tunnel 55 having airtightness and flexibility (that is, the sliding contact portion). 53 and the air chamber main body 54 are connected in an airtight state or in a state of being kept substantially airtight).

また、気室器16には、摺接部53を切換弁体15の側に付勢する摺接部用付勢手段としてのスプリングユニット61の複数個(本例では4個)を、摺接部53の周りにおいて等間隔に配置する状態で組み付け装備(詳しくは、気室器本体54と摺接部53との間に亘らせた状態に組み付け装備)してある。   In addition, a plurality of spring units 61 (four in this example) as slidable contact portion urging means for urging the slidable contact portion 53 toward the switching valve body 15 are slidably contacted with the air chamber 16. Assembling equipment (specifically, assembling equipment in a state extending between the air chamber main body 54 and the sliding contact portion 53) is arranged around the portion 53 at equal intervals.

64は、スプリングユニット61と摺接部53との間の隙間を閉塞する状態(換言すれば、スプリングユニット61と摺接部53との両方に接当する状態)でスプリングユニット61に固定連結された規制リング体であり、この規制リング体64により、気室器本体54に対する摺接部53の切換弁体15に対する遠近方向を除く方向への変位、本例では、前記遠近方向に対する直交方向(つまり、縦方向)での変位を確実に規制する。   64 is fixedly connected to the spring unit 61 in a state in which a gap between the spring unit 61 and the sliding contact portion 53 is closed (in other words, in a state of contacting both the spring unit 61 and the sliding contact portion 53). With this restriction ring body 64, the displacement of the sliding contact portion 53 with respect to the air chamber main body 54 in the direction excluding the perspective direction with respect to the switching valve body 15, in this example, the orthogonal direction to the perspective direction ( That is, the displacement in the vertical direction) is reliably regulated.

図11〜図12に示すように、前記摺接部53の右端に接続された横軸芯円筒状の左側風洞保持体56の外周面には、伸縮風洞固定ボルト(図示しない)を取り付けるための取付孔56aを周方向等間隔で多数形成してあり、また、気室器本体54の左側開口縁部(すなわち、摺接部53側の開口縁部)に接続された略円筒状の右側風洞保持体57の外周面には、伸縮風洞固定ボルト(図示しない)を取り付けるための取付孔57aを周方向等間隔で多数形成してある。   As shown in FIGS. 11 to 12, a telescopic wind tunnel fixing bolt (not shown) is attached to the outer peripheral surface of the left-side wind tunnel holding body 56 having a horizontal axis that is connected to the right end of the sliding contact portion 53. A large number of mounting holes 56a are formed at equal intervals in the circumferential direction, and a substantially cylindrical right wind tunnel connected to the left opening edge of the air chamber body 54 (that is, the opening edge on the sliding contact portion 53 side). A large number of mounting holes 57a for mounting telescopic wind tunnel fixing bolts (not shown) are formed on the outer peripheral surface of the holding body 57 at equal intervals in the circumferential direction.

そして、摺接部53に接続された左側風洞保持体56と気室器本体54に接続された右側風洞保持体57との夫々に伸縮風洞55の左右両端部の各々を伸縮風洞固定ボルトにて固定することで、伸縮風洞55の可撓性によって伸縮風洞55の風洞長さ範囲内(つまり、軸芯P方向の長さ範囲内)で、気室器本体54に対し摺接部53を切換弁体15に対する遠近方向に変位自在に構成してある。   Then, the left and right end portions of the telescopic wind tunnel 55 are respectively connected to the left wind tunnel holding body 56 connected to the sliding contact portion 53 and the right wind tunnel holding body 57 connected to the air chamber body 54 with the telescopic wind tunnel fixing bolts. By fixing, the sliding contact portion 53 is switched with respect to the air chamber main body 54 within the wind tunnel length range of the telescopic wind tunnel 55 (that is, within the length range in the axis P direction) by the flexibility of the telescopic wind tunnel 55. It is configured to be displaceable in the perspective direction with respect to the valve body 15.

58は、摺接部53の左側風洞保持体56に対し伸縮風洞55の内側に位置する状態で伸縮風洞55の左端部とともに伸縮風洞固定ボルトにて取り付けた金属製の第1補強筒であり、59は、第1補強筒58に内嵌状態で摺動可能な外径で構成され、気室器本体54の右側風洞保持体57に対し伸縮風洞55の内側に位置する状態で伸縮風洞55の右端部とともに伸縮風洞固定ボルトにて取り付けた金属製の第2補強筒である。   58 is a metal first reinforcing cylinder attached with a telescopic wind tunnel fixing bolt together with a left end portion of the telescopic wind tunnel 55 in a state of being located inside the telescopic wind tunnel 55 with respect to the left wind tunnel holding body 56 of the sliding contact portion 53; 59 has an outer diameter that is slidable in the first reinforcing cylinder 58 while being fitted inside, and is located inside the telescopic wind tunnel 55 with respect to the right wind tunnel holding body 57 of the air chamber body 54. It is the metal 2nd reinforcement cylinder attached with the telescopic wind tunnel fixing bolt with the right end part.

第1補強筒58と第2補強筒59は、風洞保持体56、57に対し上述の如く取り付けた状態において、第1補強筒58内に第2補強筒59の少なくとも一部が常に内嵌される相対筒高さ寸法で形成してあり、後述する規制リング体64が損傷した場合でも、気室器本体54に対する摺接部53の切換弁体15に対する遠近方向を除く方向への変位、本例では、前記遠近方向に対する直交方向(つまり、縦方向)での変位を摺接部53に取り付けた第1補強筒58に対する第2補強筒59の接当により規制する。   When the first reinforcing cylinder 58 and the second reinforcing cylinder 59 are attached to the wind tunnel holding bodies 56 and 57 as described above, at least a part of the second reinforcing cylinder 59 is always fitted inside the first reinforcing cylinder 58. Even when a later-described restricting ring body 64 is damaged, the sliding contact portion 53 with respect to the air chamber main body 54 is displaced in a direction other than the perspective direction with respect to the switching valve body 15. In the example, the displacement in the direction orthogonal to the perspective direction (that is, the vertical direction) is restricted by the contact of the second reinforcing cylinder 59 with the first reinforcing cylinder 58 attached to the sliding contact portion 53.

また、第1補強筒58と第2補強筒59を伸縮風洞55の内側に配置することで、伸縮風洞55内外の圧力差(伸縮風洞55外側の被処理ガスGと伸縮風洞55内側の処理済ガスG´との圧力差)により内側に押圧され易い伸縮風洞55の内側への移動を接当規制して、その内側への押圧力で伸縮風洞55に生じる面方向の引張力により伸縮風洞55が劣化するなどの不具合を抑止する。   Further, by disposing the first reinforcing cylinder 58 and the second reinforcing cylinder 59 inside the telescopic wind tunnel 55, the pressure difference between the inside and outside of the telescopic wind tunnel 55 (the gas G to be treated outside the telescopic wind tunnel 55 and the processed gas inside the telescopic wind tunnel 55 is processed. The inward movement of the telescopic wind tunnel 55 that is easily pressed inward due to the pressure difference with the gas G ′ is abutted and regulated, and the telescopic wind tunnel 55 is generated by the tensile force in the surface direction generated in the telescopic wind tunnel 55 by the inner pressing force. To prevent problems such as deterioration.

前記摺接部用付勢手段としてのスプリングユニット61は、図13、図14に示すように、気室器本体54の左側開口縁部において周方向等間隔に径方向外向きで突出形成した複数(本例では4個)の本体側フランジ片54aに対しボルト接続(図示しない)されるユニット枠62と、摺接部53の左側開口縁部において気室器本体54の本体側フランジ片54aに相対向する状態で径方向外向きに突出形成した複数の摺接部側フランジ片53aの右端面に嵌合する押圧体63との間に一対の圧縮コイルスプリング64を介装して構成してあり、ユニット枠62を介して気室器本体54にスプリング右端を固定支持させる状態(換言すれば、ユニット枠58を介して気室器本体54を反力支点とする状態)で押圧体63を弾性的に左方に押圧し、これにより、押圧体63を介して摺接部53を左方へ付勢する構成にしてある。   As shown in FIGS. 13 and 14, the spring unit 61 as the sliding contact portion urging means is formed by projecting radially outward at equal intervals in the circumferential direction at the left opening edge of the air chamber main body 54. A unit frame 62 (not shown) that is bolt-connected to (four in this example) the main body side flange pieces 54 a and the main body side flange pieces 54 a of the air chamber main body 54 at the left opening edge of the sliding contact portion 53. A pair of compression coil springs 64 are interposed between the pressing bodies 63 fitted to the right end surfaces of the plurality of sliding contact side flange pieces 53a formed to project outward in the radial direction in opposition to each other. Yes, the pressing body 63 is held in a state in which the right end of the spring is fixedly supported by the air chamber main body 54 via the unit frame 62 (in other words, the air chamber main body 54 is used as a reaction force fulcrum via the unit frame 58). Elastically pressed to the left , Thereby, it is a configuration for biasing the sliding portion 53 to the left via the pressing member 63.

前記押圧体63は、一対の圧縮コイルスプリング64の左端部に亘らせた支持片63cと、支持片63cの中央に形成した挿通孔に挿通される押圧ピン63aと、支持片63cに伝達された圧縮コイルスプリング64の押圧力を押圧ピン63aに伝達するためのナット63dと、押圧ピン63aの挿通孔からの抜け止めを阻止するナット63eとから構成してある。   The pressing body 63 is transmitted to a support piece 63c that extends over the left ends of the pair of compression coil springs 64, a pressing pin 63a that is inserted into an insertion hole formed in the center of the support piece 63c, and the support piece 63c. The nut 63d for transmitting the pressing force of the compression coil spring 64 to the pressing pin 63a and the nut 63e for preventing the pressing pin 63a from coming off from the insertion hole.

前記押圧ピン63aは、摺接部側フランジ片53aの右面に形成した被嵌合凹部53bに対する嵌合突起を左端に形成するとともに、前記ナット63d、63eを螺合するためのネジ溝を外周面のピン全長に亘って形成してあり、これにより、押圧ピン63aに対するナット63dの位置を変更自在に構成して、押圧ピン63aによる摺接部53への付勢力を変更できるようにしてある。   The pressing pin 63a has a fitting projection for the fitting recessed portion 53b formed on the right surface of the sliding contact side flange piece 53a at the left end, and has a thread groove for screwing the nuts 63d and 63e on the outer peripheral surface. Thus, the position of the nut 63d relative to the pressing pin 63a can be freely changed, and the urging force of the pressing pin 63a on the sliding contact portion 53 can be changed.

つまり、摺接部用付勢手段としてのスプリングユニット61で気室器16の摺接部53を切換弁体15の側へ付勢するとともに、これとは別に切換弁体用付勢手段としてのシリンダ50で気室器16には付勢力が非作用の状態で切換弁体15を分配器12の側へ付勢することで、摺接部用付勢手段及び切換弁体用付勢手段のそれぞれに対する独立的な調整により、気室器側シール部材25を圧接させる為の摺接部53への付勢力及び分配器側シール部材19を圧接させる為の切換弁体15への付勢力を各別に調整できるようにしてある。   That is, the spring unit 61 as the slidable contact portion urging means urges the slidable contact portion 53 of the air chamber 16 toward the switching valve body 15, and separately from this, as the switching valve body urging means. By urging the switching valve body 15 toward the distributor 12 with no urging force acting on the air chamber 16 by the cylinder 50, the sliding contact portion urging means and the switching valve body urging means By independent adjustment to each, the urging force to the sliding contact portion 53 for pressing the air chamber side seal member 25 and the urging force to the switching valve body 15 for pressing the distributor side seal member 19 are changed. It can be adjusted separately.

そして、摺接部53及び切換弁体15に対する付勢力の個別調整により、気室器16と切換弁体15との間において、気室器16の器内空間17A側の開口縁部(詳しくは、摺接部53の左側開口縁部)に装備の気室器側シール部材25を摺接部53により押圧させる形態で切換弁体15の弁底板23に対し適切な力で確実に圧接させて、気室器16と切換弁体15との間を通じて弁体器17の器内空間17Aと気室器16及び切換弁体15内との連通を防止し、この連通防止により、器内空間17A内の被処理ガスGと気室器16内の処理済ガスG′との混合を効果的且つ確実に防止するとともに、分配器12と切換弁体15との間において、分配器12の底板12aに装備の分配器側シール部材19を切換弁体15により押圧させる形態で切換弁体15の弁天板22に対し適切な力で確実に圧接させて、分配器12の底板12aと切換弁体15の弁天板22との間の隙間を通じての被処理ガス供給口33、処理済ガス排出口35、パージ用口32の相互連通を弁天板22に対する分配器側シール部材19の摺接により遮断し、その隙間連通による処理済ガスG′中への被処理ガスGの混入を効果的且つ確実に防止する。   Then, by the individual adjustment of the urging force with respect to the sliding contact portion 53 and the switching valve body 15, an opening edge (in detail) on the inner space 17 </ b> A side of the air chamber 16 between the air chamber 16 and the switching valve body 15. The air chamber side seal member 25 is pressed against the valve bottom plate 23 of the switching valve body 15 by an appropriate force in such a manner that the equipped air chamber side sealing member 25 is pressed by the sliding contact portion 53 to the left opening edge of the sliding contact portion 53. The communication between the internal space 17A of the valve body 17 and the interior of the air chamber 16 and the switching valve body 15 through the space between the air chamber 16 and the switching valve body 15 is prevented. By preventing this communication, the internal space 17A Mixing of the gas to be processed G in the gas chamber and the processed gas G ′ in the air chamber 16 is effectively and reliably prevented, and the bottom plate 12 a of the distributor 12 is disposed between the distributor 12 and the switching valve body 15. A mode in which the distributor-side seal member 19 of the equipment is pressed by the switching valve body 15 A gas supply port 33 to be processed 33 through the gap between the bottom plate 12a of the distributor 12 and the valve top plate 22 of the switching valve body 15 is securely pressed against the valve top plate 22 of the switching valve body 15 with an appropriate force. The communication between the exhaust gas discharge port 35 and the purge port 32 is blocked by the sliding contact of the distributor-side seal member 19 with respect to the valve top plate 22, and mixing of the gas G to be processed into the processed gas G 'due to the clearance communication. Prevent effectively and reliably.

駆動ユニット48におけるフレーム枠52の下面隅部(本例では、四隅)の各々には、設置架台18上を一方向(本例では、軸芯P方向)に沿って転動可能なロック機能付き転輪52a(移動手段の一例)を設けるとともに、弁体器17の下面隅部(本例では、四隅)の各々には、設置架台18上を一方向(本例では、軸芯P方向)に沿って転動自在なロック機能付き転輪17a(移動手段の一例)を設けてある。   Each of the bottom corners (four corners in this example) of the frame 52 in the drive unit 48 has a lock function that can roll along the installation base 18 in one direction (in this example, the axis P direction). Rollers 52a (an example of moving means) are provided, and each of the lower surface corners (four corners in this example) of the valve body 17 has a direction on the installation base 18 (in this example, the axis P direction). A rolling wheel 17a with a lock function (an example of a moving means) that can roll along is provided.

そのため、回転軸芯Xと駆動ユニット48との連結を解除して、駆動ユニット48を軸芯P方向に沿って切換装置T2から離脱させることで、駆動ユニット48の交換や点検を専用の空間で容易に行うことができる。   Therefore, the connection between the rotating shaft X and the drive unit 48 is released, and the drive unit 48 is detached from the switching device T2 along the direction of the axis P, so that the drive unit 48 can be replaced or inspected in a dedicated space. It can be done easily.

また、分配器12と弁体器17との連結を解除して、弁体器17を軸芯P方向に沿って切換装置T2から離脱させることで、分配器12と弁体器17との間の分配器側シール部材の点検や交換を容易に行うことができとともに、弁体器17の交換や点検を専用の空間で容易に行うことができる。   Further, the connection between the distributor 12 and the valve body 17 is released by releasing the connection between the distributor 12 and the valve body 17 and detaching the valve body 17 from the switching device T2 along the axis P direction. The distributor-side seal member can be easily inspected and replaced, and the valve body 17 can be easily replaced and inspected in a dedicated space.

なお、この場合、駆動ユニット48とともに弁体器17を切換装置T2から離脱させる離脱形態、駆動ユニット48を切換装置T2から離脱させたのち、弁体器17を単独で切換装置T2から離脱させる形態のいずれを採用してもよい。   In this case, a mode of detaching the valve body 17 from the switching device T2 together with the drive unit 48, and a mode of detaching the valve body 17 from the switching device T2 alone after the drive unit 48 is detached from the switching device T2. Any of these may be adopted.

前記設置架台18の下面隅部(本例では、四隅)の各々には、設備設置面L上を一方向(本例では、軸芯P方向)に沿って転動自在なロック機能付き転輪18a(移動手段の一例)を設けてあり、切換装置T2を専用の空間に移動させて、交換や複雑な点検などを専用の空間で容易に行うことができようにしてある。   Each of the bottom corners (four corners in this example) of the installation stand 18 has a locking function that can roll along the equipment installation surface L along one direction (in this example, the axis P direction). 18a (an example of a moving means) is provided, and the switching device T2 is moved to a dedicated space so that replacement or complicated inspection can be easily performed in the dedicated space.

以上、要するに、この蓄熱式ガス処理設備は、蓄熱式ガス処理器T1の器体接続口部8を器体横外方空間からガス給排路11を接続可能な形態で横側壁部9に形成することで、蓄熱式ガス処理器T1を設備設置面L上に載置する形態を採って、蓄熱式ガス処理器T1の実質的な器体高さを効果的に低くすると同時に、切換装置T2の切換弁体15を横軸芯周りで回転させる構成にすることで、切換装置T2の高さも効果的に低くし、これらのことにから、設備全体の高さを効果的に低くして既存の建物内部や既存の乾燥炉の下部空間などの設置スペースに対して設置し易い設備にしてある。   In short, in this regenerative gas processing facility, the housing connection port 8 of the regenerative gas processing device T1 is formed on the lateral side wall 9 in such a form that the gas supply / discharge passage 11 can be connected from the lateral lateral space. By adopting a configuration in which the regenerative gas processor T1 is placed on the equipment installation surface L, the substantial body height of the regenerative gas processor T1 is effectively reduced, and at the same time, the switching device T2 By adopting a configuration in which the switching valve body 15 is rotated around the horizontal axis, the height of the switching device T2 is also effectively reduced. It is a facility that is easy to install in installation spaces such as the interior of buildings and the lower space of existing drying furnaces.

〔別実施形態〕
次に別実施形態を列記する。
前述の実施形態では、燃焼室5を器体内部の上部に形成するとともに、複数の第1給排室6を器体内部の下部に形成し、各蓄熱室3の上端を燃焼室5に連通させ、且つ、各蓄熱室3の下端を各第1給排室6に対し個別に連通させる構成を例に示したが、燃焼室5を器体内部の下部に形成するとともに、複数の第1給排室6を器体内部の上部に形成し、各蓄熱室3の上端を各第1給排室6に対し個別に連通させ、燃焼室5に連通させ、且つ、各蓄熱室3の下端を燃焼室5に連通させる構成にしてもよい。
[Another embodiment]
Next, another embodiment will be listed.
In the above-described embodiment, the combustion chamber 5 is formed in the upper portion inside the vessel body, the plurality of first supply / discharge chambers 6 are formed in the lower portion inside the vessel body, and the upper ends of the respective heat storage chambers 3 communicate with the combustion chamber 5. In addition, the configuration in which the lower end of each heat storage chamber 3 is individually communicated with each first supply / exhaust chamber 6 is shown as an example, but the combustion chamber 5 is formed in the lower part inside the vessel body, and a plurality of first The supply / exhaust chamber 6 is formed in the upper part inside the container, and the upper end of each heat storage chamber 3 is individually communicated with each first supply / exhaust chamber 6, communicated with the combustion chamber 5, and the lower end of each heat storage chamber 3. May be configured to communicate with the combustion chamber 5.

前述の実施形態では、蓄熱式ガス処理器T1を設備設置面L上に載置する例を示したが、蓄熱式ガス処理器T1を設備設置面L上から若干浮かせた状態で配設する構成にしてもよい。   In the above-described embodiment, an example in which the regenerative gas processor T1 is placed on the equipment installation surface L has been described. However, the regenerative gas processor T1 is disposed in a state slightly lifted from the equipment installation surface L. It may be.

ガス給排路11の各々を被処理ガス導入状態と処理済ガス導出状態とに交互的に切り換える切換装置は、前述の実施形態に示した如き切換形態(すなわち、切換弁体の回転によりガス給排路11の各々を被処理ガス導入状態と処理済ガス導出状態とに交互的に切り換える切換形態)のものに限らず、種々の切換形態ものを採用することができ、例えば、ファンFの逆転運転などによりガス給排路11の各々を被処理ガス導入状態と処理済ガス導出状態とに交互的に切り換える切換形態のものなどであってもよい。   The switching device that alternately switches each of the gas supply / exhaust passages 11 between the treated gas introduction state and the treated gas lead-out state is the switching mode as shown in the above-described embodiment (that is, the gas supply by the rotation of the switching valve body). The switching paths are not limited to those in which each of the exhaust passages 11 is alternately switched between the treated gas introduction state and the treated gas derivation state, and various switching forms can be employed. The gas supply / discharge path 11 may be switched in such a manner that the gas supply / exhaust passage 11 is alternately switched between a gas to be processed introduction state and a treated gas lead-out state.

蓄熱室3、燃焼室5、第1給排室6、器体接続口部8の具体的構造、並びに、これらの連通形態などの具体的構成は種々の構成変更が可能である。   Various configurations can be changed for the specific configurations of the heat storage chamber 3, the combustion chamber 5, the first supply / exhaust chamber 6, the vessel connection port portion 8, and the communication form thereof.

複数のガス給排路11の各々を複数の器体接続口部8の各々に接続する接続形態は、種々の接続形態を採ることが可能であり、例えば、複数のガス給排路11をユニット化してガス給排路ユニットを構成するとともに、複数の器体接続口部8をユニット化して器体接続口部ユニットを構成し、ガス給排路ユニットを器体接続口部ユニットに接続することにより複数のガス給排路11の各々を複数の器体接続口部8の各々に接続する接続形態を採ってもよい。   The connection form for connecting each of the plurality of gas supply / discharge passages 11 to each of the plurality of vessel connection ports 8 can take various connection forms. For example, the plurality of gas supply / discharge passages 11 are unitized. To configure a gas supply / discharge channel unit, unitize a plurality of device connection ports 8 to configure a device connection port unit, and connect the gas supply / discharge channel unit to the device connection port unit Therefore, a connection configuration may be adopted in which each of the plurality of gas supply / discharge passages 11 is connected to each of the plurality of vessel connection ports 8.

前述の実施形態では、連絡ダクト10の蓄熱室側面を隣接第1給排室6Aの内部における平面視中央側が平面視外側よりも蓄熱室3とは反対側に位置する形態に構成する例として、天井面10aを隣接第1給排室6Aの内部における平面視中央側が平面視外側よりも蓄熱室3とは反対側に位置する傾斜面形状に形成する例を示したが、傾斜面形状に限らず、階段形状や曲面形状などであってもよい。   In the above-described embodiment, as an example in which the side surface of the heat storage chamber of the communication duct 10 is configured in such a manner that the center side in the plan view inside the adjacent first supply / discharge chamber 6A is located on the opposite side of the heat storage chamber 3 from the outside in plan view. Although the example in which the ceiling surface 10a is formed in an inclined surface shape in which the center side in the plan view inside the adjacent first supply / discharge chamber 6A is located on the opposite side of the heat storage chamber 3 from the outside in the plan view has been shown, the shape is limited to the shape of the inclined surface. Alternatively, a staircase shape or a curved surface shape may be used.

前述の実施形態では、連絡風路を金属で構成する例を示したが、これに限らず、種々の材料で構成してもよい。   In the above-mentioned embodiment, although the example which comprises a connection air path with a metal was shown, you may comprise not only this but with various materials.

切換装置T2の具体的構成は、前述の実施形態で示した如き構成に限らず、種々の構成変更が可能である。   The specific configuration of the switching device T2 is not limited to the configuration shown in the above-described embodiment, and various configuration changes can be made.

上述の如く、切換装置T2の構成を変更する場合において、例えば、切換弁体15の回転軸Xを横軸芯にするのに代え、斜め軸芯や縦軸芯などに構成してもよい。   As described above, when the configuration of the switching device T2 is changed, for example, instead of the rotation axis X of the switching valve body 15 being a horizontal axis, it may be configured as an oblique axis or a vertical axis.

また、例えば、切換弁体用付勢手段をシリンダ50で構成するのに代え、圧縮コイルスプリング、引張コイルスプリング、モータ、ゴムなどの弾性体などにより構成してもよく、同様に、分配器用付勢手段を圧縮コイルスプリングで構成するのに代え、引張コイルスプリング、シリンダ、モータ、ゴムなどの弾性体などにより構成してもよい。   Further, for example, instead of configuring the switching valve body urging means with the cylinder 50, it may be configured with an elastic body such as a compression coil spring, a tension coil spring, a motor, rubber, etc. The biasing means may be constituted by an elastic body such as a tension coil spring, a cylinder, a motor, or rubber instead of being constituted by a compression coil spring.

また、例えば、切換弁体15の回転軸Xを3つの分割軸部を着脱自在に連結して構成するのに代え、2つ又は4つ以上の分割軸部を連結して構成したり、或いは、分割軸部を連結するのではなく1つの軸部だけで構成してもよい。   Further, for example, instead of configuring the rotation axis X of the switching valve body 15 by detachably connecting three divided shaft portions, two or four or more divided shaft portions are connected, or Instead of connecting the divided shaft portions, it may be constituted by only one shaft portion.

また、例えば、弁体器17や駆動ユニット48の移動手段を構成するのに、設置架台18上を転動可能なロック機能付き転輪17a、52aを弁体器17や駆動ユニット48の側に設けるのに代え、ロック機能付き転輪を設置架台18の側に設けたり、設置架台18上にレールを亘らせて、そのレール上を滑動又は摺動するレール受けやレール上を転動する転輪を弁体器17や駆動ユニット48に設けてもよく、或いは、駆動ユニット48の移動方向を規制する障害物を設置架台18上に設けたりしてもよい。   Further, for example, in order to constitute the moving means of the valve body 17 and the drive unit 48, the rolling wheels 17a and 52a with a lock function that can roll on the installation base 18 are arranged on the valve body 17 and the drive unit 48 side. Instead of providing, a roller wheel with a lock function is provided on the installation base 18 side, or a rail is passed over the installation base 18, and a rail receiver that slides or slides on the rail or rolls on the rail. Rollers may be provided in the valve body 17 and the drive unit 48, or obstacles that restrict the moving direction of the drive unit 48 may be provided on the installation base 18.

同様に、設置架台18の移動手段を構成するのに、設備設置面L上を転動可能なロック機能付き転輪18aを設置架台18の側に設けるのに代え、ロック機能付き転輪を設備設置面Lの側に設けたり、設備設置面L上にレールを亘らせて、そのレール上を滑動又は摺動するレール受けやレール上を転動する転輪を設置架台18に設けてもよく、或いは、設置架台18の移動方向を規制する障害物を設備設置面Lに設けたりしてもよい。   Similarly, in order to constitute the moving means of the installation stand 18, instead of providing the lock wheel 18a with a lock function capable of rolling on the equipment installation surface L on the installation stand 18 side, the wheel with the lock function is provided. Even if it is provided on the installation surface L side or a rail is passed over the equipment installation surface L, a rail receiver that slides or slides on the rail or a rolling wheel that rolls on the rail is provided on the installation base 18. Alternatively, an obstacle that regulates the moving direction of the installation base 18 may be provided on the equipment installation surface L.

また、例えば、伸縮風洞55を気密性と可撓性を備える布で構成するのに代え、紙、シート、ゴムなどの弾性体、蛇腹状の金属や樹脂などで構成してもよい。   Further, for example, the telescopic wind tunnel 55 may be made of an elastic body such as paper, a sheet, or rubber, a bellows-like metal or resin, instead of being made of a cloth having airtightness and flexibility.

また、例えば、分配器12と切換弁体15との間に介装する分配器側シール部材19を分配器12に装備するのに代え、切換弁体15に装備する構成にしてもよい。   Further, for example, instead of providing the distributor 12 with the distributor-side seal member 19 interposed between the distributor 12 and the switching valve body 15, the switching valve body 15 may be equipped.

また、例えば、切換弁体15と気室器16との間に介装する気室器側シール部材25を気室器16に装備するのに代え、切換弁体15に装備する構成にしてもよい。   Further, for example, instead of installing the air chamber device side seal member 25 interposed between the switching valve body 15 and the air chamber device 16 in the air chamber device 16, the switching valve body 15 is equipped. Good.

また、例えば、分配器12と弁体器17とを横方向に並べて装備するのに代え、これらを斜め方向又は縦方向に並べて装備する構成してもよい。   Further, for example, instead of arranging the distributor 12 and the valve body 17 side by side in the horizontal direction, these may be arranged side by side or in the vertical direction.

また、例えば、被処理ガスGを供給するガス供給路45を弁体器17内の器内空間17Aに連通接続し、ファンFにより処理済ガスG′を排出するガス排出路46を弁体器17内における切換弁体15及び気室器16周りの器内空間17Aに連通接続し、処理済ガスG′の一部をガス排出路46から取り出してパージ用ガスG″として供給するパージ用ガス供給路47を気室器16の内部に形成のパージ用チャンバ20に連通接続する例を示したが、ファンFにより被処理ガスGを供給するガス供給路45を弁体器17内の器内空間17Aに連通接続し、処理済ガスG′を排出するガス排出路46を弁体器17内における切換弁体15及び気室器16周りの器内空間17Aに連通接続し、パージ用ガスG″を排出してガス供給路45に導入するパージ用ガス排出路46を気室器16の内部に形成のパージ用チャンバ20に連通接続する構成にしてもよい。   Further, for example, the gas supply path 45 for supplying the gas G to be processed is connected to the internal space 17A in the valve body 17 and the gas discharge path 46 for discharging the processed gas G ′ by the fan F is used as the valve body. 17 is connected to the switching valve body 15 and the internal space 17A around the air chamber 16, and a part of the treated gas G ′ is taken out from the gas discharge passage 46 and supplied as the purge gas G ″. Although an example in which the supply path 47 is connected to the purge chamber 20 formed inside the air chamber 16 is shown, the gas supply path 45 for supplying the gas G to be processed by the fan F is provided in the valve body 17. A gas exhaust passage 46 for communicating with the space 17A and exhausting the treated gas G 'is communicated with the switching valve body 15 in the valve body 17 and the internal space 17A around the air chamber 16, and the purge gas G ″ Is discharged and introduced into the gas supply path 45 The purge chamber 20 formed inside of the purge gas discharge passage 46 to the air chamber 16 may be configured to communicatively connected.

この場合、燃焼室における処理済ガスG′の一部をパージ用ガスG″として燃焼室5から更に他の蓄熱室3に通過させて、その後、その蓄熱室3に連通の第1給排室6、その第1給排室6に連通の器体接続口部8、その器体接続口部8に連通のガス給排路11、そのガス給排路11に連通の第2給排室14、その第2給排室14に連通の給排口14A、及び、その給排口14Aに対向連通する切換弁体15の弁天板22に形成のパージ用口32を通じ、切換弁体15のパージ用室38へ導くとともに、それに続き、切換弁体15の筒状回転軸24に形成の第1パージ用連通口24a、筒状回転軸24及び第2連結回転軸27の内部空間、第2連結回転軸27に形成の第3パージ用連通口27a、パージ用チャンバ20を通じてパージ用ガス排出路47へ導出し、そのパージ用ガス排出路47を通じて被処理ガスGに合流させる形態で、被処理ガスGの通過後、次に処理済ガスG′を通過させるに先立ち各蓄熱室3にパージ用ガスG″を通過させる。   In this case, a part of the treated gas G ′ in the combustion chamber is passed as a purge gas G ″ from the combustion chamber 5 to the other heat storage chamber 3 and then the first supply / exhaust chamber communicated with the heat storage chamber 3. 6, a body connection port portion 8 communicating with the first supply / discharge chamber 6, a gas supply / discharge passage 11 communicating with the device connection port portion 8, and a second supply / discharge chamber 14 communicating with the gas supply / discharge passage 11 The purge of the switching valve body 15 through the supply / discharge port 14A communicating with the second supply / discharge chamber 14 and the purge port 32 formed in the valve top plate 22 of the switching valve body 15 communicating with the supply / discharge port 14A oppositely. The first purge communication port 24a formed in the cylindrical rotary shaft 24 of the switching valve body 15, the internal space of the cylindrical rotary shaft 24 and the second connecting rotary shaft 27, the second connection Purge gas exhaust through the third purge communication port 27 a formed in the rotary shaft 27 and the purge chamber 20. In the form where the gas to be processed G is led to the passage 47 and merged with the gas to be processed G through the purge gas discharge passage 47, the heat storage chamber 3 is purged after passing the gas to be processed G and then the processed gas G '. The working gas G ″ is passed.

被処理ガスGは、塗装設備の排ガスなどに限らず、燃焼室5での燃焼により処理し得るガスであれば、どのようなガスであってもよく、処理目的も浄化や脱臭に限られるものではない。   The gas to be treated G is not limited to the exhaust gas of the painting equipment, but may be any gas as long as it can be treated by combustion in the combustion chamber 5, and the purpose of treatment is limited to purification and deodorization. is not.

燃焼室5に装備する燃焼手段は、バーナー7に限らず、電気ヒーターなどであってもよく、さらに、各蓄熱室3において蓄熱材4aよりも燃焼室5の側に触媒を配設して、触媒燃焼により被処理ガスGを処理するようにしてもよい。   The combustion means equipped in the combustion chamber 5 is not limited to the burner 7 but may be an electric heater or the like. Further, in each heat storage chamber 3, a catalyst is disposed on the combustion chamber 5 side of the heat storage material 4a. The gas to be processed G may be processed by catalytic combustion.

本発明に係る蓄熱式ガス処理設備の側面図Side view of regenerative gas processing equipment according to the present invention 本発明に係る蓄熱式ガス処理設備の平面図The top view of the heat storage type gas processing equipment concerning the present invention 隣接第1給排室の横断面図(連絡ダクト直交方向断面図)Cross section of adjacent first supply / discharge chamber (cross section in the direction perpendicular to the connecting duct) 図2のA−A線断面図AA line sectional view of FIG. 図2のB−B線断面図BB sectional view of FIG. 第1給排室とガス給排路との接続状態を示す説明図Explanatory drawing which shows the connection state of a 1st supply / discharge chamber and a gas supply / discharge path 切換装置の側面断面図Side view of switching device 切換装置の側面断面図Side view of switching device 切換装置要部の分解斜視図Exploded perspective view of the main part of the switching device 切換弁体の分解斜視図Disassembled perspective view of switching valve body 切換装置要部の側面断面図Side sectional view of the main part of the switching device 切換装置要部の分解斜視図Exploded perspective view of the main part of the switching device 切換装置要部の側面断面図Side sectional view of the main part of the switching device スプリングユニットの斜視図Spring unit perspective view 本発明に係る蓄熱式ガス処理設備の機能説明図Functional explanatory diagram of a regenerative gas processing facility according to the present invention

符号の説明Explanation of symbols

T1 蓄熱式ガス処理器
T2 切換装置
G 被処理ガス
G′ 処理済ガス
3 蓄熱室
4a 蓄熱材
5 燃焼室
5a 燃焼手段
6 給排室(第1給排室)
8 器体接続口部
9 横側壁部
10 連絡風路
11 ガス給排路
12 分配器
14A 給排口
15 切換弁体
45 ガス供給路
46 ガス排出路
T1 Thermal storage gas processor T2 Switching device G Processed gas G 'Processed gas 3 Thermal storage chamber 4a Thermal storage material 5 Combustion chamber 5a Combustion means 6 Supply / exhaust chamber (first supply / exhaust chamber)
8 Body connection port portion 9 Side wall portion 10 Communication air passage 11 Gas supply / discharge passage 12 Distributor 14A Supply / discharge port 15 Switching valve body 45 Gas supply passage 46 Gas discharge passage

Claims (5)

蓄熱材を収容した複数の蓄熱室と、被処理ガスを燃焼させる燃焼手段を備えた燃焼室と、前記蓄熱室の各々について蓄熱室を介して前記燃焼室に導入される被処理ガス及び燃焼室から蓄熱室を介して導出される処理済ガスを通過させる複数の給排室とを器体内部に形成し、
前記複数の蓄熱室を器体内部の上下中間部において横方向に並べて、各蓄熱室の上端又は下端のうちの一端を前記燃焼室に連通させ、且つ、各蓄熱室の他端を前記給排室の各々に個別に連通させる構造にするとともに、
前記給排室の各々について給排室を介して器体外部から前記燃焼室に被処理ガスを導入する被処理ガス導入状態と給排室を介して器体外部に処理済ガスを導出する処理済ガス導出状態とに交互的に切換可能な複数のガス給排路の各々に対する器体接続口部を形成してある蓄熱式ガス処理器であって、
前記複数の器体接続口部を、器体横外方空間から前記ガス供給路を接続可能な形態で横側壁部に形成してある蓄熱式ガス処理器。
A plurality of heat storage chambers containing a heat storage material, a combustion chamber provided with combustion means for combusting a gas to be processed, and a gas to be processed and a combustion chamber introduced into the combustion chamber via the heat storage chamber for each of the heat storage chambers A plurality of supply and discharge chambers through which the processed gas derived from the heat storage chamber is passed are formed inside the container body,
The plurality of heat storage chambers are arranged in the horizontal direction at the upper and lower intermediate portions inside the body, and one end of each heat storage chamber is communicated with the combustion chamber, and the other end of each heat storage chamber is connected to the supply / discharge In addition to a structure that allows each room to communicate individually,
For each of the supply / exhaust chambers, a process gas introduction state in which the process gas is introduced into the combustion chamber from the outside of the container through the supply / discharge chamber, and a process for deriving the processed gas to the outside of the container through the supply / discharge chamber A regenerative gas processing device in which a vessel connection port portion is formed for each of a plurality of gas supply / exhaust passages that can be switched alternately to a spent gas derivation state,
The regenerative gas processing device in which the plurality of container connection ports are formed in a lateral wall portion in a form in which the gas supply path can be connected from a container lateral outer space.
前記複数の器体接続口部を、複数の横側壁部のうちの一つの横側壁部に集中的に形成してある請求項1記載の蓄熱式ガス処理器。   The regenerative gas processor according to claim 1, wherein the plurality of vessel connection ports are formed intensively on one of the plurality of side wall portions. 前記複数の器体接続口部を集中的に形成した横側壁部から離れた前記給排室とそれに対する器体接続口部とを、前記横側壁部に隣接する給排室を貫通する連絡風路を介して連通させる構成にしてある請求項2記載の蓄熱式ガス処理器。   The communication air passing through the supply / discharge chamber adjacent to the lateral wall portion, through the supply / discharge chamber separated from the lateral wall portion in which the plurality of device body connection ports are concentratedly formed, and the body connection port portion corresponding thereto. The regenerative gas processor according to claim 2, wherein the regenerator is configured to communicate with each other through a path. 前記連絡風路を、前記横側壁部に隣接する給排室の内部における前記蓄熱室とは反対側端に配置してある請求項3記載の蓄熱式ガス処理器。   The regenerative gas processor according to claim 3, wherein the communication air passage is disposed at an end opposite to the heat storage chamber inside the supply / discharge chamber adjacent to the lateral side wall portion. 請求項1〜4のいずれか1項に記載の蓄熱式ガス処理器を用いた蓄熱式ガス処理設備であって、A regenerative gas processing facility using the regenerative gas processor according to any one of claims 1 to 4,
前記ガス給排路の各々を前記被処理ガス導入状態と前記処理済ガス導出状態とに交互的に切り換える切換装置を器体外部に設け、  A switching device for alternately switching each of the gas supply / exhaust passages between the treated gas introduction state and the treated gas derivation state is provided outside the container body,
前記切換装置を、前記複数のガス給排路に対し個別に連通される複数の給排口を有する分配器と、ガス供給路から前記ガス給排路に導入する被処理ガスを通過させる前記給排口とガス給排路からガス排出路に導出する処理済ガスを通過させる給排口との両方が存在する状態を保ちながら、前記分配器に対する摺接状態での横軸芯周り又は斜め軸芯周りの回転により各給排口を被処理ガス通過状態と処理済ガス通過状態とに交互的に切り換える切換弁体とから構成するとともに、  The switching device includes a distributor having a plurality of supply / exhaust ports individually connected to the plurality of gas supply / exhaust passages, and the supply gas that passes the gas to be treated introduced from the gas supply passage to the gas supply / exhaust passage. While maintaining the state where both the exhaust port and the supply / exhaust port through which the treated gas led out from the gas supply / exhaust passage passes, the horizontal axis around the horizontal axis or the oblique axis in the sliding contact state with respect to the distributor While comprising a switching valve body that alternately switches between the supply gas exhaust port and the processed gas passage state by rotation around the core,
前記蓄熱式ガス処理器の前記器体接続口部それぞれに対して前記ガス給排路それぞれの一端を個別に接続し、且つ、前記切換装置における前記給排口それぞれに対してガス給排路それぞれの他端を個別に連通させる構成にしてある蓄熱式ガス処理設備。  One end of each of the gas supply / discharge paths is individually connected to each of the body connection ports of the regenerative gas processor, and each of the gas supply / discharge paths is connected to each of the supply / discharge ports in the switching device. Regenerative gas processing equipment that is configured to communicate with the other end of each.
JP2006345408A 2006-12-22 2006-12-22 Thermal storage type gas processor and thermal storage type gas processing equipment using the same Active JP4814780B2 (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP2006345408A JP4814780B2 (en) 2006-12-22 2006-12-22 Thermal storage type gas processor and thermal storage type gas processing equipment using the same

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
JP2006345408A JP4814780B2 (en) 2006-12-22 2006-12-22 Thermal storage type gas processor and thermal storage type gas processing equipment using the same

Publications (2)

Publication Number Publication Date
JP2008157510A JP2008157510A (en) 2008-07-10
JP4814780B2 true JP4814780B2 (en) 2011-11-16

Family

ID=39658610

Family Applications (1)

Application Number Title Priority Date Filing Date
JP2006345408A Active JP4814780B2 (en) 2006-12-22 2006-12-22 Thermal storage type gas processor and thermal storage type gas processing equipment using the same

Country Status (1)

Country Link
JP (1) JP4814780B2 (en)

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP6057048B2 (en) * 2012-03-16 2017-01-11 株式会社大気社 Thermal storage gas processing equipment

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP3606789B2 (en) * 2000-06-14 2005-01-05 大阪ガスエンジニアリング株式会社 Thermal storage deodorizer
JP4118207B2 (en) * 2003-08-08 2008-07-16 株式会社大気社 Thermal storage gas processing equipment
JP2006300399A (en) * 2005-04-20 2006-11-02 Kondo Unyu-Kiko Co Ltd Rotary regenerative combustion type deodorizing apparatus

Also Published As

Publication number Publication date
JP2008157510A (en) 2008-07-10

Similar Documents

Publication Publication Date Title
KR100969828B1 (en) Rotary valve assembly for voc heat recycling burning system and heat recycling burning system with it
US5375622A (en) Multiport valve including leakage control system, particularly for a thermal regenerative fume incinerator
KR101185512B1 (en) Heat storage type gas processing apparatus
US6892750B2 (en) Switching valve
JP4814780B2 (en) Thermal storage type gas processor and thermal storage type gas processing equipment using the same
US6749815B2 (en) Switching valve seal
CA2543286C (en) Regenerative thermal oxidizer
KR20200066873A (en) Entry-level type apparatus for regenerative thermal oxidation process
JP2006010247A (en) Rotary directional control valve and heat accumulating gas processing system using this valve
JP4814704B2 (en) Thermal storage gas processing equipment
JP4776457B2 (en) Thermal storage gas processing equipment
CA2478870C (en) Heated seal air for valve and regenerative thermal oxidizer containing same
JP4526912B2 (en) Operation method of regenerative gas treatment device and regenerative gas treatment device used in the operation method
JP4118207B2 (en) Thermal storage gas processing equipment
KR100704639B1 (en) Regenerative combustion plant
KR101772566B1 (en) Ventilation valve unit for an regenerative thermal oxidation process system
JP4439391B2 (en) Thermal storage gas processing equipment
JP4204499B2 (en) Rotary switching valve and heat storage type gas processing apparatus using the same
KR100382870B1 (en) Rotary adsorption/desorption gas treating apparatus
JP4159451B2 (en) Heat-resistant hermetic wall structure, regenerative gas treatment device, and adsorption / desorption gas treatment device
JP3831532B2 (en) Thermal storage type exhaust gas treatment equipment
JP2007183019A (en) Heat storage type deodorizing device
WO2020217857A1 (en) Suction processing device
KR102411851B1 (en) Distribution rotor for Horizontal Type Rotor Distributor of Regenerative Thermal Oxydizer
JPH06126122A (en) Adsorption and desorption-type air cleaning apparatus

Legal Events

Date Code Title Description
A621 Written request for application examination

Free format text: JAPANESE INTERMEDIATE CODE: A621

Effective date: 20081201

A977 Report on retrieval

Free format text: JAPANESE INTERMEDIATE CODE: A971007

Effective date: 20110608

A131 Notification of reasons for refusal

Free format text: JAPANESE INTERMEDIATE CODE: A131

Effective date: 20110616

A521 Request for written amendment filed

Free format text: JAPANESE INTERMEDIATE CODE: A523

Effective date: 20110715

TRDD Decision of grant or rejection written
A01 Written decision to grant a patent or to grant a registration (utility model)

Free format text: JAPANESE INTERMEDIATE CODE: A01

Effective date: 20110811

A01 Written decision to grant a patent or to grant a registration (utility model)

Free format text: JAPANESE INTERMEDIATE CODE: A01

A61 First payment of annual fees (during grant procedure)

Free format text: JAPANESE INTERMEDIATE CODE: A61

Effective date: 20110826

R150 Certificate of patent or registration of utility model

Ref document number: 4814780

Country of ref document: JP

Free format text: JAPANESE INTERMEDIATE CODE: R150

Free format text: JAPANESE INTERMEDIATE CODE: R150

FPAY Renewal fee payment (event date is renewal date of database)

Free format text: PAYMENT UNTIL: 20140902

Year of fee payment: 3

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250

R250 Receipt of annual fees

Free format text: JAPANESE INTERMEDIATE CODE: R250