選煤廠污水處理案例解析(含壓濾機應用)
一、選煤污水的危害分析
二、選煤污水的組成與特性
三、選煤污水處理的核心標準與復用要求
四、壓濾機在選煤污水處理中的核心應用
五、選煤污水處理常用藥劑與適配技巧
六、案例總結
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養殖廢水處理改造工程案例_50m3/d奶牛養殖廢水達標回用項目
一、工程概況
二、設計進水水量及水質
三、污水處理排放標準
四、工藝設計分析
五、工藝流程及說明
(一)工藝流程
(二)工藝說明
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高效隔膜板框壓濾機市政污泥工程案例
一、引言
在當前環保治理不斷升級的背景下,污泥脫水干化作為河湖清淤、城市污水處理中的關鍵環節,其處理效率、處理質量及成本控制直接影響工程整體效益。目前,國內外主流的機械脫水干化技術主要分為帶式壓濾機脫水、離心機脫水和板框壓濾機脫水三大類。其中,高效隔膜板框壓濾機在普通板框式壓濾機的基礎上進行了全方位優化改進,具備自動化程度高、泥餅含水率低、生產效率高、運行穩定、處理成本低等核心優勢,已逐漸成為河湖污泥處理、城市污水處理等領域的優選設備,在國內得到廣泛應用與推廣。
二、高效隔膜板框壓濾機工作原理
高效隔膜板框壓濾機的工作原理簡潔且高效,核心結構由交替排列的濾板和濾框組成一組完整濾室。濾板表面設有專用溝槽,其凸出部位用于支撐濾布,濾框與濾板的邊角處均設有通孔,組裝后可形成完整的流體通道,用于通入懸浮液、洗滌水及引出濾液。濾板與濾框兩側的把手支托在橫梁上,通過壓緊裝置將濾板與濾框緊密壓緊,濾板與濾框之間的濾布同時起到密封墊片的作用,保障過濾過程的密封性。
具體工作流程分為四個階段:一是壓緊階段,通過液壓系統將濾板、濾框緊密壓緊,形成密封濾室;二是進料階段,由供料泵將懸浮液壓入濾室,濾渣在濾布表面逐漸沉積形成泥餅,直至濾室被完全填充;三是過濾階段,濾液穿過濾布,沿濾板表面的溝槽流至邊角通道,實現集中排出;四是卸渣與循環階段,過濾完成后,松開壓緊裝置,卸除濾渣、清洗濾布,重新壓緊濾板與濾框,進入下一個工作循環。整個流程實現自動化運行,操作便捷,大幅減少人工干預。
三、核心應用參數
高效隔膜板框壓濾機的應用效果,與進料參數、工藝優化密切相關,核心應用參數如下:
1. 泥漿濃度與調理:針對城市湖泊、河道疏浚的泥漿,初始質量濃度通常約為8%,濃度較低,直接處理會導致效率低、電耗高。為提升處理效益,需先對泥漿進行濃縮、調理處理,處理后泥漿質量濃度可提升至25%,此舉可使壓濾機脫水效率提升150%以上,有效降低運行成本。
2. 進料工藝優化:板框壓濾機單個周期處理的固體污泥量,通常為設計最大值的85%~100%,即濾室腔體的污泥充盈率,充盈率越高、進料時間越短,生產效率越高。工程中常用渣漿泵作為供漿設備,經工藝優化后,采用雙進料泵供漿模式可進一步提升效率:供漿初期采用高流量低揚程渣漿泵,快速填充濾腔,當充盈率達到85%以上后,切換為低流量高揚程渣漿泵,在進一步壓榨淤泥的同時,提升濾腔充盈率,增加固體污泥處理量。
四、工程實例
(一)工程概況
湖泊清淤項目,總設計清淤方量約102萬m3,項目核心需求為實現污泥脫水干化一體化處理,確保處理后濾餅含水率不大于40%,尾水懸浮物含量不大于20mg/L,最終實現污泥減量化、無害化處理,滿足環保排放及后續處置要求。該項目選用高效隔膜板框壓濾機作為核心脫水設備,構建完整的脫水干化工藝體系。
(二)施工工藝
1. 污泥濃縮與調理:該湖泊疏浚泥漿初始質量濃度約為8%,首先通過自然重力沉淀方式進行濃縮處理,濃縮后泥漿質量濃度提升至25%,脫水效率較初始狀態提升200%以上。濃縮后的污泥進入調節池,向池內添加生石灰與粉煤灰組合固化劑(其中生石灰占濾餅比重2%,粉煤灰占濾餅比重3%)。該組合固化劑可有效破壞污泥的親水膠體結構,改善污泥脫水特性,同時優化污泥孔隙結構,增強污泥透水性,進一步提升壓濾機脫水速率。固化劑與污泥在調節池內充分攪拌混合均勻后,由渣漿泵輸送至高效隔膜板框壓濾機進行脫水干化處理。
2. 壓濾脫水過程:高效隔膜板框壓濾機單個工作循環主要分為5個步驟,依次為:壓緊濾板→進料→隔膜壓榨→反吹→卸料,完成后重新壓緊濾板進入下一個循環。具體操作如下:進料前由液壓系統將濾板緊密壓緊,確保密封;進料初期采用高流量渣漿泵供漿10~15分鐘,將濾室腔體基本填充完畢后,切換為高揚程渣漿泵供漿5~10分鐘;關閉進料泵,開啟壓榨閥門,維持壓榨壓力在1MPa左右,持續10~15分鐘,直至出液嘴水流由連續出水變為點滴出水,關閉壓榨閥門;打開反吹氣閥,反吹10秒左右,排出壓濾機中心進料管內殘留污泥及隔膜腔內殘余濾液;壓榨結束后,壓緊板后退,通過拉板小車實現自動卸料。
該項目中,壓濾機單個循環周期約為45~60分鐘,處理后濾餅厚度可達35~40mm,濾餅含水率≤40%,尾水懸浮物含量≤20mg/L,完全滿足項目設計要求及相關環保標準。
五、運行成本與工程效益
該湖泊清淤項目中,高效隔膜板框壓濾機的運行成本優勢顯著。經核算,單噸污泥處理成本約為44.46元,遠低于傳統污泥石灰干化技術(單噸處理成本約93.7元)、離心機脫水技術(單噸處理成本約92.26元)及帶式壓濾機脫水技術(單噸處理成本約242.84元),大幅降低了工程整體運行成本,具備極強的經濟效益。
六、結論
高效隔膜板框壓濾機脫水干化技術,是一種低成本、高效率、高穩定性的城市污泥及河湖淤泥處理解決方案,其自動化運行模式可減少人工成本,低含水率濾餅可實現污泥減量化,低成本優勢可提升工程整體效益,完全滿足當前環保治理的核心需求。
本次清淤工程的實踐表明,高效隔膜板框壓濾機脫水干化工藝運行穩定、處理效果達標、經濟效益顯著,應用取得了圓滿成功。該工程的施工經驗、工藝參數及成本控制方法,可為國內同類河湖清淤、城市污水處理項目提供可靠的參考依據,助力環保工程提質增效,推動污泥處理行業高質量發展。
壓濾機咨詢:18851718517
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在當前工業生產和環保治理不斷升級的背景下,filter press作為重要的固液分離設備,市場需求持續增長。選擇一家實力可靠、技術成熟的壓濾機廠家,成為眾多企業關注的重點。蘇東壓濾機廠家立足行業多年,專注于壓濾機設備的研發、制造與服務,為客戶提供穩定、高效的壓濾解決方案。
一、蘇東壓濾機廠家的定位與實力
蘇東壓濾機廠家是一家集設計、生產、銷售于一體的專業壓濾機制造企業,主要產品包括廂式壓濾機、板框壓濾機、隔膜壓濾機及全自動壓濾機等。廠家依托成熟的生產體系和技術團隊,不斷提升產品性能,滿足不同行業用戶對過濾效率和設備穩定性的要求。
在生產過程中,蘇東壓濾機廠家注重設備的實用性與耐用性,通過合理的結構設計和嚴謹的裝配工藝,使壓濾機在高強度工況下依然能夠保持穩定運行。
二、產品結構與技術優勢
蘇東壓濾機廠家生產的壓濾機在結構設計上科學合理,過濾面積配置靈活,能夠根據客戶物料特性進行選型。濾板采用高強度材料,耐壓性能好,密封效果可靠,有效降低跑料和漏料現象。
同時,液壓系統運行平穩,壓緊力穩定,確保過濾過程連續高效。電控系統操作簡便,支持自動進料、壓緊、卸料等流程,降低人工操作強度,提高生產效率。
三、廣泛的應用領域
憑借穩定的性能和良好的適應性,蘇東壓濾機廠家產品已廣泛應用于環保污水處理、污泥脫水、化工過濾、礦山選礦、食品加工等多個行業。針對不同行業物料含固量、顆粒大小及腐蝕性的差異,廠家可提供針對性的壓濾機配置方案,幫助客戶實現理想的過濾效果。
四、嚴格的質量控制體系
蘇東壓濾機廠家始終將產品質量放在重要位置,從原材料采購到成品出廠,均執行嚴格的質量檢測流程。每一臺壓濾機在出廠前都需經過試運行和性能檢測,確保設備各項指標符合設計要求,為客戶長期穩定使用提供保障。
五、完善的服務與支持
在服務方面,蘇東壓濾機廠家建立了完善的售前、售中、售后服務體系。售前階段,技術人員根據客戶工況提供選型建議;設備交付后,提供安裝指導與操作培訓;使用過程中,售后團隊可及時響應客戶需求,協助解決設備運行問題。
六、持續發展與未來方向
隨著行業技術不斷進步,蘇東壓濾機廠家將持續推進產品升級和技術創新,在提高自動化水平、降低能耗、延長設備使用壽命等方面不斷優化,為客戶創造更高的使用價值。
concluding remarks
綜合來看,蘇東壓濾機廠家憑借扎實的制造基礎、穩定的產品性能和完善的服務體系,已成為眾多企業信賴的壓濾機供應商。未來,廠家將繼續深耕壓濾機領域,為工業生產和環保事業提供更加可靠的設備支持。
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【行業領先技術】蘇東壓濾機采用高強度濾板與智能控制系統,實現高效固液分離,過濾精度高,處理能力強,廣泛應用于化工、冶金、環保、食品等領域,滿足不同行業的過濾需求。
【節能耐用設計】優化結構設計,能耗降低30%,運行更穩定;選用耐磨抗腐蝕材料,設備壽命大幅延長,減少維護成本,為企業創造長期價值。
【智能自動化操作】配備PLC智能控制,一鍵啟停,實時監控運行狀態,操作簡便,安全可靠,大幅提升生產效率,降低人工成本。
【定制化服務】根據客戶需求提供個性化方案,支持濾板材質、過濾面積等靈活配置,確保每一臺壓濾機都能精準匹配生產要求。
選擇蘇東壓濾機,就是選擇高效、節能、省心的過濾專家!立即咨詢,獲取專屬解決方案!
關鍵詞:壓濾機、高效過濾設備、固液分離機、工業壓濾機、蘇東壓濾機廠家、智能壓濾機、化工過濾設備
]]>1 Diaphragm filter press workflow and principle
The diaphragm filter press duty cycle is divided into the feed stage, the filter press stage, the membrane drum stage, the blowback stage, the discharge stage, and the preparation stage for the next duty cycle, such as cleaning the filter cloth and pressing the filter plate. The diaphragm filter press operating cycle timeline is shown in Figure 1. The blowback, discharge, and preparation phases have a constant time, which is integrated for ease of calculation and is referred to as T0. The feed phase time, T1, starts when the sludge is pumped to the filter press and fills the entire chamber, which is also a constant value. The filter press stage time T2 starts at 0 and stops at t2, when the sludge continues to be fed at the rated pressure P2 and filtered. At T3, the filter press stops feeding, the diaphragm plates on both sides of the diaphragm are filled with water or air at rated pressure p3 (p3 > p2) to expand the diaphragm chamber, compressing the volume of the sludge cake inside the chamber and further filtering the sludge cake until t3.
Since the filtration speed in the filter press and membrane drum stages decreases with time, the efficiency of the filter press in treating sludge begins to decrease in the later stages of operation. Therefore, the efficiency of the diaphragm filter press can be improved by optimising the filter press time T2 and the membrane drum time T3.
2 Based on Fluent simulation of filter press working process
The purpose of this simulation is to simulate the filtration process of the filter press, record the filtrate volume at each time point, and find out the relationship between the filtrate volume and time in the filtration stage, the specific filtration speed[2, 7-8] and time, and the relationship between the filtration pressure and the limiting filtration volume of the sludge, so as to provide a basis for the prediction of the mathematical model for the other working stages of the filter press.
2.1 Establishment of Filter Chamber Models Fluent pre-processing was carried out using Gambit software to establish the geometric model of a single filter chamber of the filter press and mesh the chamber. The calculation method was "Standard k-ε model", the discrete format was "QUICK", the pressure interpolation method was "PRESTO! The pressure interpolation method is "PRESTO!" and the pressure-velocity coupling method is "PISO". The main parameters were as follows: chamber diameter of 300 mm; solid-phase particle diameter of 0.01 mm; chamber thickness of 10 mm; rated filtration pressure of 0.2-3.0 MPa; solid-phase density of 1,051 kg/m3; filtration time of 30 min; porosity of 201 TP3T; two-phase flow rate of 951 TP3T; and coefficient of inertial resistance of 3.5×107 ; The coefficient of inertial resistance is 3.5×107; the coefficient of viscosity resistance is 1.2×1015; and the dynamic viscosity is 0.02 Pa?s.
2.2 Simulation results Under the filtration pressure of 0.2~1.4 MPa, the relationship between the total volume of filtrate V and time t of the four groups is shown in Fig. 2. As can be seen from Fig. 2, the total volume of filtrate gradually increases with time and tends to be close to a certain limit value; the higher the pressure, the faster the filtrate speed, and the greater the ultimate filtration volume.The liquid-phase flow velocity in the outer cross-section of the porous medium is plotted at a filtration pressure of 1.4 MPa. The specific filtration velocity q versus time t is shown in Fig. 4. From Fig. 4, it can be seen that the specific filtration velocity will surge to a certain value at the beginning, continue to rise for a short period of time, reach the maximum value, and then gradually decrease with the increase of time; the main reason for the transient increase of the specific filtration velocity is that the sludge particles are bonded at the beginning of the filtration process, and the diameter of the particles increases, which leads to the decrease of the specific surface area of the sludge layer and the increase of the porosity.
3 Mathematical modelling of two-phase flow filtration
3.1 Conventional filtration calculation methods
The traditional method of measuring specific resistance usually considers the mud cake incompressible and measures the slope of the curve K of dt/dV-V[12] , which is derived as a proportional function of K[6, 13] . The specific resistance r is derived as a proportional function of K [6, 13], which leads to the specific resistance r. However, this method regards the cake as incompressible and the specific resistance does not change with time, which is obviously not consistent with the filtration situation of two-phase flow of sludge in the filter chamber of the diaphragm filter press. In addition, the diaphragm filter press has many workflows, the filtration stage is a constant-pressure feed filtration, and the volume of the filter chamber in the membrane drum stage changes with time, which makes the variation of the specific resistance complicated, and it is difficult to express the relationship between q and t in equation (3).
3.2 Calculation method based on the simulation results By simulating and recording the curve of the total volume of sludge filtrate V(t) versus time t and the curve of the specific filtration rate q versus time t, the expression of the V-t function is obtained by fitting the calculation.
3.2.1 Feed stage During the feed stage, the filtration volume is approximated to be 0 L. The sludge is fed at a certain flow rate to reach the final M1, which is the chamber volume.
From its derivative (Figure 4), it can be seen that: first there will be a short-term increase, and then gradually decrease, and finally converge to 0 L. Therefore, the exponential form is more in line with the change rule of the total amount of filtrate over time, and can be fitted to the V(t)-t curve of the filtration pressure stage by the least squares method. Set 2 / 22 22 2 ( ) e , 0, 0, 0, 0 b t Vt a a b t t = ><< ≤ (4) The simulated V2-t curves of 8 groups under the conditions of 0.2~3.0 MPa are fitted by the least squares method, and the results are shown in Table 1. From Table 1, the curves of filtration pressure p2 and parameter a2 are shown in Fig. 5. The ultimate filtration capacity a2 increases with the increase of pressure, but the rate of increase is from fast to slow, and tends to a constant value, after reaching the constant value, the further increase of pressure can not make the mud cake further filtration[14] .
The parameter b2 hardly changes with filtration pressure under certain sludge characteristics and filter press operating parameters. 3.2.3 Membrane Stage Assuming that the filter press continues to be fed at the pressure p3 during the membrane stage, the ultimate filtrate volume a3 = ka2 (where k is the ratio of the membrane filtrate volume to the filtration filtrate volume). However, the membrane stage stops feeding, the diaphragm plate with a certain pressure on the compression of the cake, by reducing the volume of the filter chamber to achieve the purpose of filtration, the limit of the filtrate volume must be less than a3, so a3 is not the limit of the filtrate volume of the membrane stage. Therefore, a3 is not the limiting filtrate volume in the membrane stage. In this paper, a3 is the virtual limiting filtrate volume in the membrane stage, and V3' is the virtual filtrate volume in the membrane stage, whose value is only a mathematical assumption, not the real filtrate volume.
3.2.4 Filter Press Blowback, Unloading and Preparation for Cleaning After the membrane is blown, a blowback process is performed to clean the pipework of any residual slurry and filtrate. This is followed by the unloading process and preparation for the next cycle. The time for this phase is essentially constant. 3.2.5 Optimisation of filter press operating time points As shown in Figure 1, the non-filtration sum time T0+T1=t0 and the filter press filtration time T2+T3=t3, the filter press operating cycle T=t0+t3, with filtration time T2=t2 and membrane drumming time T3=t3-t2. Assuming that the original sludge water content is η0, the final water content of the cake during the drumming process at t=t3 reaches ηf, which is the final water content of the sludge dewatering process. At t=t3, the final water content of the sludge cake in the membrane drum process reaches ηf, which is the standard of sludge dewatering.
In practice, since the expansion of the diaphragm at the membrane expansion stage is not arbitrarily large, the pressure of the diaphragm plate will not be able to act sufficiently on the cake if the cake does not reach a certain thickness, which limits the scope of application of this method to calculate the optimum filter press time. Based on the above problems, the minimum feed quantity Mmin should be set according to the diaphragm expansion performance of the diaphragm plate of the diaphragm filter press, and when the theoretically calculated filtration press time T2 corresponds to the total feed quantity M>Mmin, T2 calculated by the above method is the optimal filtration press time, and T3 is the optimal membrane drumming time. When the total amount of feed M corresponding to the theoretically calculated filter press time T2 < Mmin, the time T2′ to reach Mmin is the optimum filter press time.
4 Optimisation of filter press working cycle in sludge treatment plant 4.1 Filter press working parameters A sludge treatment plant treats 500 m3 of sludge with a water content of 95% per day, and four XAGZ200/1250-30u diaphragm filter presses are designed to work simultaneously for 24 hours, which cannot actually complete the work task. At present, the working cycle of the filter press in this plant is T=210 min, in which the preparation time is 20 min, the feeding time is 10 min, the filter press time is 120 min, the membrane drum time is 30 min, the blowback time is 10 min, and the unloading time is 20 min. The parameters of the XAGZ200/1250-30u diaphragm filter press are as follows: the area is 200 m2 , the number of chambers is 80, the outer diameter of the filter plate is 10 m2 , and the number of filter plates is 10 m2 . The parameters of XAGZ200/1250-30u diaphragm filter press are as follows: the area is 200 m2 ; the number of filter chambers is 80; the outer diameter of the filter plate is 1 250 mm×1 250 mm; the thickness of the filter chamber is 30 mm; the centre feed, the rated filtration pressure is 0.8 MPa, and the rated pressing pressure is 1.6 MPa. The amount of filtrate during the working process of the filter press was recorded, as shown in Table 2.At the end of the filter press process, the total amount of filtrate was 14.36 m3 . The total amount of filtrate at the end of the drum stage was 15.17 m3 , and the water content of the final cake was 60.4%. The sludge processing rate of the filter press was u=0.083 m3 /min.
4.2 Optimisation of the timing of the various operating phases of the filter press
According to the time setting of the original filter press workflow, each filter press can work for 6 cycles per day, and the daily processing capacity of the 4 filter presses is about 416.64 m3 , which is not able to complete the daily production task. After optimisation, the working cycle of filter press is about 2 h, and the daily operation is 12 cycles, the daily production capacity can be 613.44 m3 . The plant actually operates according to the cycle proposed in this paper, and lets one of the machines rest and standby in turn while completing the task, which not only meets the requirements of the daily production.It also gives the filter presses more downtime and overhaul time, which helps to extend the service life of the filter presses.
5 Conclusions 1) Based on Fluent simulationsfilter pressThe relationship between the total volume of filtrate V and time t under different pressures in the filtration stage was investigated, and a least-squares method was used to fit the functional expression of the curve to obtain the relationship between the total volume of filtrate and the pressure. 2) The concept of virtual filtrate volume V3′ in the membrane stage was proposed, i.e., the total filtrate volume under the assumption of continuing to feed at the membrane pressure p3 without changing the chamber volume. In this way, the mathematical relationship between the actual filtrate volume V3 at the membrane drum stage and the time t is obtained, and the mathematical relationship between the filter press efficiency u and the filter press time t2 is also obtained. 3) Optimising the time of each working stage of diaphragm filter press in a sludge treatment plant, the sludge treatment efficiency was improved by 37.7%.
]]>壓濾機的品牌也有很多,如蘇東,suton等
污水處理設備壓濾機的使用方法如下1::
- 濾布的選型。
- 板框壓濾機應首先將濾布放入壓濾機中。
- 將污水進入濾室,然后加壓將污水送入壓濾機,將污泥水壓干。
- 將過濾后的清水放出。
- 將過濾室中的污泥清除,清洗濾布。
- 按照順序操作,不斷循環。
污水處理設備壓濾機:18851718517
]]>- 過濾面積180平米。體積1.6立方
- It adopts PLC control to achieve automatic feeding, filtering, pressing, discharging, washing and unloading operations.
- The frame is made of carbon steel and stainless steel for corrosion resistance and long life.
- The filter plate is moulded as a whole, with good sealing and no leakage.
- Non-standard design can be carried out according to the user's needs to meet a variety of special working conditions.
180平方程控隔膜壓濾機在過濾壓力、過濾面積、過濾效果等方面都有很大的優勢,被廣泛應用于化工、制藥、冶金、礦山、食品、環境工程等領域。
]]>- 處理面積為100平米。
- 電源為380V。
- 整機功率按照自動化的程度設計實際功率。
- 過濾介質:濾板、濾布過濾。
- The frame is made of carbon steel and stainless steel for corrosion resistance and long life.
- The filter plate is made of reinforced polypropylene plate with strong corrosion resistance and long life.
- The filter plate is moulded as a whole, with good sealing and no leakage.
- It adopts PLC control to achieve automatic feeding, filtering, pressing, discharging, washing and unloading operations.
XAYZGF100/1000-UK技術參數
| XAYZGF100/1000-UK技術參數 | |
| Specification | XAYZGF100/1000-UK |
| filtration area | 100m2 |
| Filter chamber volume | 1.5m3 |
| 過濾板數量 | 30塊(包括頭尾板) |
| 壓榨板數量 | 30塊 |
| Filter plate specifications | 1000×1000×70/72 |
| 濾板/壓榨板材質 | Reinforced polypropylene/TPE |
| Filter cloth specifications | 2200×1060 |
| Number of filter cloths | 60塊(包括頭尾) |
| filtration pressure | ≤0.6MPa |
| pressing pressure | ≤1.6MPa |
| 最大液壓保護壓力 | 25MPa |
| Compacting working pressure | 16~20MPa |
| Filter plate acid and alkali resistance | 2<PH<12 |
| 過濾工作溫度 | 0-70°C |
| Cake thickness | (壓榨后)20-25mm |
| Matching power | 4KW |
| 出液方式 | 暗流 |
| 壓緊方式 | 液壓壓緊、自動保壓 |
| Pulling plate method | Automatic pulling plate |
| 外型尺寸 | 6760×1520×1500 |
| 單機重量 | 6400Kg |
XAYZGF100/1000-UK (以單臺機計算)
| serial number | name (of a thing) | 數量 | 備注 |
| 1 | rackmount | 1套 | 材質:鋼焊接,大梁采用工字鋼梁,材質Q345 |
| 2 | 濾板/隔膜板 | 30/30塊 | 增強聚丙烯/TPE彈性體
(包括頭尾板) |
| 3 | filter cloth | 60塊 | 耐強酸(物料PH=2) |
| 4 | 拉板機構 | 1套 | 拉板器、鏈輪鏈條采用304封閉鏈條 |
| 5 | 壓緊裝置 | 1套 | 油缸45# |
| 6 | 控制箱 | 1頂 | PLC—西門子
主要電氣元件:施耐德? |
| 7 | 自動翻板
集液盤 |
1套 | 材質316L |
| 8 | 液壓站 | 1臺 | 液壓元件上海華島 |
| 泵—上海申福 | |||
| 上海力超電機 |
該設備,長度為10m,濾板尺寸為80,型號為100平方,過濾介質為濾板、濾布過濾,處理量需要結合實際的物料。這些參數可以幫助您更好地了解隔膜壓濾機的規格和功能。100平方暗流隔膜壓濾機已被廣泛應用于各種工業廢水處理領域的固液分離。
]]>- 過濾面積800平米。
- High filtration pressure up to 4MPa.
- The filter plate is made of reinforced polypropylene plate with strong corrosion resistance and long life.
- The frame is made of carbon steel and stainless steel for corrosion resistance and long life.
- Non-standard design can be carried out according to the user's needs to meet a variety of special working conditions.
- The filter plate is moulded as a whole, with good sealing and no leakage.
- Non-standard design can be carried out according to the user's needs to meet a variety of special working conditions.
- It adopts PLC control to achieve automatic feeding, filtering, pressing, discharging, washing and unloading operations.
隔膜廂式壓濾機是一種工業設備,用于固液分離。隔膜廂式壓濾機已被廣泛應用于化工、制藥、冶金、礦山、食品、環境工程等領域的固液分離。
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