Tag Archives: waste incinerator

Pet Crematorium

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Basic Info.

Export Markets:Global

Additional Info.

Trademark:clover
Origin:Clover

Product Description

We want to refresh or change incinerator with new one the incinerator contain 3 units each unit 400kg/h, if u interest to make job with as pls contact me to send u drawing and details. (Baghdad ) 
Our hospitals require 3 X Medical Waste Incinerator Units (designed to 
Burn medical waste load capacity of 50kg/hr, with calorific values 
Ranging from 2, 300 kJ. Kg to 30, 000 kJ/kg at a designed thermal rate 
Of 1, 440, 000 kJ/hr. 
I was browsing through your website and noted that Model: YZ-50 or 
YD-50 might be the the desired (specified) incinerator unit. Please 
Find attached animal incinerators and other waste, animal incinerators and other waste. De, animal incinerators costs, animal incinerators manufacturers, animal incinerators price, our incinerator specifications. 
I kindly request you to send me a quotation of your Medical Waste 
Incinerator Units, detailed specs and features plus freight costs from 
Your location to Port Moresby, Papua New Guinea. 
MEDICAL WASTE INCINERATOR SPECIFICATIONS 
Capacity (4000 kg/day). 
The unit should have the following features: 
* Automatic feeding 
* Automatic ash / leftovers removal 
* Flue gas filtration system. 
* The technical & financial offer should include installation & testing and staff training. 
***The offer should be itemized. 
IMPORTANT INFORMATION: 
1. Emission standards: ( EU ) 
2. Waste type: Hazardous Medical Waste 
3. Approximate moisture content: Max. 30% 
4. Glass content: Max. 15% 
5. Building Roof Height: 8 meters 
6. Height of chimney above roof (required): At least 3 meters 
7. Fuel to be used: No. 2 ( diesel ) ( Fuel specifications attached ) 
8. Power: 380 V, 3 phase 
9. Space available inside the existing building: (Bidders should visit the building to choose the best location for installation coordinating with university engineers) 
10. Waste filled in (max. 70X120 cm ) polyethylene bags (Amman ) 
I am looking at purchasing 10-17 medical waste incinerators. Please could you give me your best price and latest catalogue for the following

Items/Model TS10(PLC) TS20(PLC) TS30(PLC) TS50(PLC) TS100(PLC)
Burn Rate 10 kg/hour 20 kg/hour 30 kg/hour 50 kg/hour 100 kg/hour
Feed Capacity 20kg 40kg 60kg 100kg 200 kg
Control Mode PLC PLC PLC PLC PLC
Combustion Chamber 100L 210L 330L 560L 1200L
Internal Dimensions 50x50x40cm 65x65x50cm 75x75x60cm 100x80x70cm 120x100x100cm
Secondary Chamber 50L 110L 180L 280L 600L
Smoke Filter Chamber Yes Yes Yes Yes Yes
Feed Mode Manual Manual Manual Manual Manual
Voltage 220V 220V 220V 220V 220V
Power 0.5Kw 0.5Kw 0.5Kw 0.7Kw 0.7Kw
Oil Consumption (kg/hour) 5.4–12.6 7.8–16.3 10.2–20 12.1–24 14–28
Gas Consumption (m3/hour) 6.2–11.4 8–15.7 9.8–20 9.9–26.1 10–32.2
Temperature Monitor Yes Yes Yes Yes Yes
Temperature Protection Yes Yes Yes Yes Yes
Oil Tank 100L 100L 100L 100L 200L
Feed Door 30x30cm 45x40cm 55x50cm 70x55cm 80x60cm
Chimney 3Meter 3Meter 5Meter 5Meter 10Meter
Chimney Type Stainless Steel Stainless Steel Stainless Steel Stainless Steel Stainless Steel
1st. Chamber Temperature 800degree–1000degree 800degree–1000degree 800degree–1000degree 800degree–1000degree 800degree–1000degree
2nd. Chamber Temperature 800degree–1000degree 800degree–1000degree 800degree–1000degree 800degree–1000degree 800degree–1000degree
Residency Time 2.0 Sec. 2.0 Sec. 2.0 Sec. 2.0 Sec. 2.0 Sec.
Gross Weight 1500kg 2200kg 3000kg 4500kg 6000kg
External Dimensions 140x90x120cm 160x110x130cm 175x120x140cm 230x130x155cm 260x150x180cm

Baltimore teens take out the trash

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Youth battle a waste incinerator.

It’s the threat of dangerous air pollution that has students at Curtis Bay’s Benjamin Franklin High School leaving the classroom and demonstrating in the streets of Baltimore.

In Curtis Bay, a neglected waterfront neighborhood at the southwestern fringes of Baltimore, an alliance of environmental activists and neighborhood groups—including an energetic and creative band of high school students—has succeeded in holding off the construction of an enormous trash incinerator project.

The students wowed members of the Baltimore Board of Education this May with a presentation that mixed carefully researched environmental and public health analysis with a hip-hop routine that had board members up on their feet. Greg Sawtell, an organizer with Baltimore-based United Workers (one of several organizations allied against the incinerator), says conversations with school board members since then have left him optimistic that they will oppose the project.

Even though preparation work on the incinerator began last year, full-scale construction is stalled, and the projected completion date has been pushed to 2016 from an initial estimate of 2013. Opponents are reluctant to claim sole credit for the delays, as there have also been financing and regulatory issues, but believe their efforts are sharpening scrutiny and slowing progress.

Talk of the so-called trash-to-energy incinerator plant began some five years ago, after chemical manufacturer FMC Corp closed a pesticide plant, eliminating 130 jobs (including 71 union jobs with the United Steelworkers) and leaving vacant a large parcel of land zoned for heavy industry. The site straddles the Curtis Bay and Fairfield neighborhoods of the city, parts of which have large African-American populations. To many political and community leaders in this deindustrialized and job-starved section of the city—which lies far from the famed Inner Harbor or Fells Point entertainment districts—it seemed like a boon when Energy Answers Inc., an Albany, New York-based power development company, appeared on the scene to propose a plant that would burn commercial and construction waste to produce electricity. Energy Answers billed the plant as a way to restore up to 200 jobs and provide clean, low-cost energy. The proposal came with enthusiastic endorsements from local political leaders, especially Maryland Gov. Martin O’Malley and city Mayor Stephanie Rawlings-Blake.

Initially, Energy Answers struggled to find loans and missed a deadline to secure federal stimulus money. But in May 2011, the project got a big boost when O’Malley signed legislation to help make the plant profitable through a complicated pollution credits scheme that would funnel cash to Energy Answers for generating so-called clean power. (A few days later, Energy Answers gave $100,000 in campaign contributions to the Democratic Governors Association, chaired by O’Malley.)

But for locals, the bloom was already coming off the rose. It had emerged that an estimated 400 to 600 exhaust-spewing trucks carrying waste tires, metals, plastics and construction materials would travel through the streets of Curtis Bay every day to feed the plant. The incinerator itself would burn up to 4,000 tons of waste a day for decades— raising even more alarming public health concerns. In a recent Baltimore Sun op-ed urging cancellation of the project, Gwen DuBois, of Chesapeake Physicians for Social Responsibility, said the plant could emit dioxin, mercury and other heavy metals, which can cause cancer and other diseases.

“What a lot of people don’t realize is just how dirty these plants really are,” says Mike Ewall, founder and co-director of Energy Justice Network, a national organization devoted to helping communities fight dirty energy development. “They are much worse than coal or anything else. And this would be the biggest such plant in the country.” Curtis Bay is already the most polluted zip code in Maryland, Ewall notes, adding that low-income neighborhoods of color are often used as dumping grounds precisely because they lack the political power to fight back.

It’s the threat of dangerous air pollution that has students at Curtis Bay’s Benjamin Franklin High School leaving the classroom and demonstrating in the streets of Baltimore. In their largest action, in late 2013, more than 100 protesters marched from the school to the site of the proposed incinerator—just a mile away. A related petition has garnered more than 2,000 signatures.

Recent Benjamin Franklin graduate Audrey Rozier is a leader of Free Your Voice, the student group agitating to stop the incinerator, as well as the co-author of a rap song devoted to the campaign. “We have our rights according to the amendments / But why do we feel like we’ve been so resented / Ignored, shoved to the side where opinions don’t matter,” goes one verse.

Rozier says the song, which she has performed all over the city, has helped educate the local community and a broader Baltimore audience. “What was amazing to me in the beginning was that people outside the community were going to [build the incinerator], but the people who live here didn’t know anything about it,” she says. “I think that’s changed.”

That disconnect between the political elite and the communities most affected by its decisions is at the heart of the fight over the Curtis Bay incinerator, says Sawtell. In Baltimore and elsewhere, decisions on economic development policies are made by a political and economic elite with little or no input from the working-class residents who must live day-to-day with the consequences. “Community members we’ve talked to say no one asked their opinion before the project was announced,” says Sawtell. “Somehow I think if it was the children of Gov. O’Malley, or the children of Mayor Rawlings-Blake, who were going to be poisoned, the decision would be different.”

The campaign is drawing increasing support, most recently from the nearby Anne Arundel County chapter of the NAACP. Meanwhile, enthusiasm for the plant among politicians seems to have cooled in the face of the protests, Sawtell says, with near-silence on the issue from Mayor Rawlings-Blake in the past few years. The Democratic candidate for governor in this year’s election, Anthony Brown, declined to take a position.

If the construction delays are any indication, even Energy Answers may be losing interest, although the company tells In These Times it’s in “confidential discussions for waste and energy sales” and plans to proceed with the project. Sawtell, however, believes that a major push from opponents now could kill the plan once and for all.

 

by: http://www.radiofree.org/us/baltimore-teens-take-out-the-trash/


PLC Incinerator (TS50 PLC)

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Basic Info.

Model NO.:TS50 PLC
Pullution Sources:Solid Waste Processing
Processing Methods:Combustion
Export Markets:Global

Additional Info.

Trademark:Clover
Packing:Full Container
Standard:50 kg per hour
Origin:China
Production Capacity:1500 Units/Year

Product Description

Nanjing Clover Medical Technology Co., Ltd. Is a leading waste incinerator manufacturer in China. We are local manufacturer and one of the largest exporter of China. Pyrolytic incinerator equipment technical is main waste treatment all of the world, for Medical Waste, Animal Incineration, Pet cremation and other Solid wste. The capacity from 10kgs/Hr. To 500kgs/Hr., up to 6ton per day. Presently, we supply different series for local customer requirements and pet crematorium incinerators china price, pet crematorium manufacturers italy, pet crematorium petaling jaya, pet crematoriums, pet crematory equipment china, pet crematory equipment manufacturer, design updated incinerator with our leading technology. The updated design feature of our range of incinerators make them one of the most cost effective in the world. 
Key Features: 
* All models with Dual combustion chamber. 
* Stainless Steel chimney/stack, long lifetime. *according to order 
* High temperature, long lifetime of incinerator. 
* Free or minimum installation on site. 
* High burn rate, from 10kgs to 500kgs per hour, up to 6ton per day. 
* PLC Control Plane. *according to order 
* New Design for pet animal cremation business. 
* One year warranty on incinerator and parts in stock. 
Application Scope: 
1. Hospital& clinic: Iatric Waste, Infectious Waste, Dressing, Bio-Waste, Medicine. 
2. Slaughter House &Pet Hospital &Farm: Dead Animal, Bio-Waste. 
3. Community & Sea Port & Station: Municipal Solid Waste, etc. 
4. Laboratories, Remote Locations, Disaster Relief Operations, Animal Cremation

Items/Model TS50(PLC)
Burn Rate 50 kg/hour
Feed Capacity 100kg
Control Mode PLC
Combustion Chamber 560L
Internal Dimensions 100x80x70cm
Secondary Chamber 280L
Smoke Filter Chamber Yes
Feed Mode Manual
Voltage 220V
Power 0.7Kw
Oil Consumption (kg/hour) 12.1–24
Gas Consumption (m3/hour) 9.9–26.1
Temperature Monitor Yes
Temperature Protection Yes
Oil Tank 100L
Feed Door 70x55cm
Chimney 5Meter
Chimney Type Stainless Steel
1st. Chamber Temperature 800–1000 degree
2nd. Chamber Temperature 1000-1200 degree
Residency Time 2.0 Sec.
Gross Weight 4500kg
External Dimensions 230x130x155cm

Incinerator Crematory

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Basic Info.

Pullution Sources:Solid Waste Processing
Processing Methods:Combustion
Export Markets:Global

Additional Info.

Trademark:clover
Origin:Nanjing

Product Description

Nanjing Clover Medical Technology Co., Ltd., local in Nanjing city, China. CLOVER is manufacturer of medical product, waste incinerator and other environmental protection equipment. The market network across over the territory of China and more than 30 countries throughout the world. 
CLOVER supply medical equipment, medical waste incinerators, china health care waste incinerator manufacturer, china hog farms incinerator, china hospital incinerator, china household incinerator, china incenirator medical waste, pet animal cremator, other solid waste treatment equipment, clean room equipment, fan filter units, air filter, etc. We supply technology service, installation service and customer made. 
We are one of the largest waste incinerator manufacturer and exporter of China. Pyrolytic incinerator technical is main waste treatment method all over the world, for Medical Waste, Animal Incineration, Pet cremation and other Solid waste. Presently, we supply small and large scale incinerators as local customer requirements and design updated incinerator with our leading technology. 
Nanjing Clover Medical Technology Co., Ltd. 
Tel: +86-25-8461 0201 
Fax: +86-25-8461 0406 
Add: RM. 7411, No. 58 Yunjin Rd., Nanjing, China 210019

Medical Waste Incinerator

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Basic Info.

Model NO.:medical waste incinerator design
Export Markets:Global

Product Description

Pyrolytic incineration technical is traditional waste treatment way for many years. All over the world, in many countries, people anti incinerator because the incinerator will produce a large Dioxin in the smoke. "Dioxins" refers to a group of toxic chemical compounds that share certain chemical structures and biological characteristics. Dioxins can be released into the environment through forest fires, backyard burning of trash, certain industrial activities, and residue from past commercial burning of waste. Dioxins break down very slowly and past releases of dioxins from both incinerators in hospitals, incinerators in unkraine, incinerators italy, incinerators lab scale, incinerators manufacturer china, incinerators manufacturers, man-made and natural sources still exist in the environment. Anyhow, we have to remind that, this is large scale incineration pant, generally more than 30 ton per day. This is a social problem, to analyze and suggest ways in different angles from the public, government, economic development, environmental protection, technology development, etc. 

A Model animal crematory burning rate from 20-400kgs per hour. Heavy duty combustion chamber and suit for large animal cremation. 

Secondary Chamber & Mix-Combustion Chamber. Residency time 2.0 sec. In post combustion chamber. Virtually smoke and smell free. 

Smoke Filter Chamber with filter brick, Virtually smoke and smell free after burning. 

Italy original oil or gas burner, quality reliable. It suit for diesel oil, natural gas, LPG gas. 

User guider, full installation and operation document for customer.

Items/Model A1500 A2400 A4000 A5500
Burning Rate *animal 90 kgs/Hr. 150 kgs/Hr. 200 kgs/Hr. 400 kgs/Hr.
Feed Capacity *animal 120 kgs 200 kgs 300 kgs 500 kgs
Equipment Weight 7000 kgs 8300 kgs 13000 kgs 16500 kgs
Picture  
Primary Chamber (Liters) 1500 2400 4000 5500
Secondary Chamber (Liters) 500 1200 1500 1500
External Dimensions (cm) 240x170x380 260x220x420 320x220x460 360 x 220 x 475
Internal Dimensions (cm) 150x100x96 220x110x100 257x147x108 300 x 147 x 125
Oil Tank(Liters) 500 500 500 500
Door Opening (cm) 59 x 81 90 x 110 108 x 128 108 x 128
Chimney (M) 10 10 14 14
Chimney Type Stainless Steel Stainless Steel Stainless Steel Stainless Steel
Secondary Chamber  YES YES YES YES
Mix-Combustion Chamber YES YES YES YES
Smoke Filter Chamber YES YES YES YES
Combustion Fuel Oil/Gas Oil/Gas Oil/Gas Oil/Gas
Residency Time 2.0 Sec. 2.0 Sec. 2.0 Sec. 2.0 Sec.
Temperature Monitoring YES YES YES YES

FFP2 Breathing mask machine

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平面口罩机参数:

Semi-Automatic Mask Machine

Power supply: 3.3KW mono phase

Mask Size: 175mm*80-100mm (two or three layers)

Nonwoven (GMS): 10-50g

Capacity: 120 to 150pcs/min

Dimension(L*W*H):3800mm*500mm*1400mm

Net Weight: about 1000kg

 

焊接机参数:

Welding Machine

Capacity: 5 to 10pcs/min

Power supply: 8.5KW mono phase

Compressed Air connection: 0.5 to 0.7Mpa

Dimension(L*W*H): 900mm*650mm*1380mm

Net weight: approx. 50kg

 

KN95口罩机参数:

N95 Mask Machine

Capacity: 130 to 160pcs/min

Dimension(L*W*H): 1037*855*1780

Power Supply 15.3kw mono phase

Net Weight: approx.: 1500kg


Zhangjiagang Tengxiang Machinery Co., Ltd.
Mobile: 0086-13962221749(whatsapp)
Wechat: chncheumg

Face Mask Machine for Coronavirus Disease COVID-19



HICLOVER – Medical Environmental 

 

Waste Incinerators
Medical Waste Incinerator
Pet Animal Cremation
Solid Waste Incinerator

Tel:  +86-25-8461 0201   
Mobile: +86-13813931455(whatsapp/wechat)
Website: www.hiclover.com  
Email: [email protected]
Email: [email protected]  
Nanjing Clover Medical Technology Co.,Ltd.

 

2020-04-06


Related

incinerators for sale

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incinerators for sale

get HICLOVER new incinerators for sale, call us +86-25-8461 0201 and receive free quotation document from us. We supply single combustion chamber, dual glazing chambers, three combustion chambers and multi-combustion chambers waste incinerators for lab, hospital, clinic, medical center, hygiene clinical waste destruction with medical disposable, biological waste, medical plastic waste, toxic waste, red bag waste, needle disposal, gauze and bandages, sealed sharp containers, pathological waste, trace-chemotherapeutic wastes, etc..

Items/Model TS10(PLC) TS20(PLC) TS30(PLC) TS50(PLC) TS100(PLC)
Burn Rate 10 kg/hour 20 kg/hour 30 kg/hour 50 kg/hour 100 kg/hour
Feed Capacity 20kg 40kg 60kg 100kg 200 kg
Control Mode PLC PLC PLC PLC PLC
Combustion Chamber 100L 210L 330L 560L 1200L
Internal Dimensions 50x50x40cm 65x65x50cm 75x75x60cm 100x80x70cm 120x100x100cm
Secondary Chamber 50L 110L 180L 280L 600L
Smoke Filter Chamber Yes Yes Yes Yes Yes
Feed Mode Manual Manual Manual Manual Manual
Voltage 220V 220V 220V 220V 220V
Power 0.5Kw 0.5Kw 0.5Kw 0.7Kw 0.7Kw
Oil Consumption (kg/hour) 5.4–12.6 7.8–16.3 10.2–20 12.1–24 14–28
Gas Consumption (m3/hour) 6.2–11.4 8–15.7 9.8–20 9.9–26.1 10–32.2
Temperature Monitor Yes Yes Yes Yes Yes
Temperature Protection Yes Yes Yes Yes Yes
Oil Tank 100L 100L 100L 100L 200L
Feed Door 30x30cm 45x40cm 55x50cm 70x55cm 80x60cm
Chimney 3Meter 3Meter 5Meter 5Meter 10Meter
Chimney Type Stainless Steel Stainless Steel Stainless Steel Stainless Steel Stainless Steel
1st. Chamber Temperature 800℃–1000℃ 800℃–1000℃ 800℃–1000℃ 800℃–1000℃ 800℃–1000℃
2nd. Chamber Temperature 1000℃-1200℃ 1000℃-1200℃ 1000℃-1200℃ 1000℃-1200℃ 1000℃-1200℃
Residency Time 2.0 Sec. 2.0 Sec. 2.0 Sec. 2.0 Sec. 2.0 Sec.
Gross Weight 1500kg 2200kg 3000kg 4500kg 6000kg
External Dimensions 140x90x120cm 160x110x130cm 175x120x140cm 230x130x155cm 260x150x180cm

Programme on Small Scale Medical Waste Incinerators for Primary Health Care Clinics in South Africa

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TABLE OF CONTENTS

  1. OBJECTIVE OF THE PROGRAMME 4
  2. STRUCTURE OF THE PROGRAMME 4
  3. COLLABORATORS INVOLVED IN THE PROGRAMME 4
  4. STAKEHOLDERS INVOLVED IN THE PROGRAMME 4
  5. LABORATORY TRIALS 5
  6. FIELD TRIALS 13

 

 

 

1.     OBJECTIVE OF THE PROGRAMME

 

The objective of the programme is to select technical criteria suitable for tender specification purposes that will enable the South African Department of Health to obtain the services and equipment necessary for the primary health care clinics to carry out small-scale incineration for the disposal of medical waste.

 

2.     STRUCTURE OF THE PROGRAMME

 

The test programme is being carried out in phases, as follows:

Phase 1         A scoping study to decide the responsibility of the different parties and

consensus on the test criteria and boundaries of the laboratory tests. The criteria for accepting an incinerator on trial was approved by all parties involved.

Phase 2         Laboratory tests with a ranking of each incinerator and the selection of the incinerators to be used in the field trials.

Phase 3         Completion of field trials, to assess the effectiveness of each incinerator under field conditions.

Phase 4         Preparation of a tender specification and recommendations to the DoH for the implementation of an ongoing incineration programme.

 

This document provides feedback on phases 2 and 3 of the work.

 

 

 

3.     COLLABORATORS INVOLVED IN THE PROGRAMME

 

SA Collaborative Centre for Cold Chain Management SA National Department of Health

CSIR

Pharmaceutical Society of SA World Health Organisation UNICEF

 

 

 

4.     STAKEHOLDERS INVOLVED IN THE PROGRAMME

 

The following stakeholders participated in the steering committee:

 

  • Dept of Health (National & provincial levels) (DoH)
  • Dept of Occupational Health & Safety (National & provincial levels)
  • Dept of Environmental Affairs & Tourism (National & provincial levels) (DEAT)
  • Dept of Water Affairs & Forestry (National & provincial levels) (DWAF)
  • Dept of Labour (National & provincial levels) (DoL)
  • National Waste Management Strategy Group
  • SA Local Government Association (SALGA)
  • SA National Civics Organisation (SANCO)
  • National Education, Health and Allied Workers Union (NEHAWU)

 

 

  • Democratic Nurses Organisation of SA (DENOSA)
  • Medecins Sans Frontieres
  • SA Association of Community Pharmacists
  • Mamelodi Community Health Committee
  • Pharmaceutical Society of SA
  • CSIR
  • UNICEF
  • WHO
  • SA Federation of Hospital Engineers

 

 

International visitors:

  • Dr Luiz Diaz – WHO Geneva and International Waste Management , USA
  • Mr Joost van den Noortgate – Medecins Sans Frontieres, Belgium

 

 

 

 

5.     LABORATORY TRIALS

 

5.1.   Objective of the laboratory trials

 

  • Rank the performance of submitted units to the following criteria:

y Occupational safety

y Impact on public health from emissions

y The destruction efficiency

y The usability for the available staff

 

  • The panel of experts for the ranking consisted of a:

y Professional nurse; Mrs Dorette Kotze from the SA National Department of Health

y Emission specialist; Dr Dave Rogers from the CSIR

y Combustion Engineer; Mr Brian North from the CSIR

 

5.2.   Incinerators received for evaluation

 

Name used in report Model no. Description Manufacturer
C&S Marketing

incinerator

 SafeWaste Model Turbo

2000Vi

 Electrically operated fan supplies combustion air

– no auxiliary fuel

 C&S Marketing cc.
Molope Gas incinerator Medcin 400 Medical

Waste Incinerator

 Gas-fired incinerator Molope Integrated

Waste Management
Molope Auto incinerator Molope Auto Medical

Waste Incinerator

 Auto-combust incinerator – uses wood

or coal as additional fuel to facilitate incineration

 Molope Integrated

Waste Management

 

Name used in report Model no. Description Manufacturer
PaHuOy

incinerator

 Turbo Stove Auto-combust unit,

using no additional fuel or forced air supply

 Pa-Hu Oy

 

 

5.3.   Emission testing: laboratory method

 

Sampling of emissions followed the US-EPA Method 5G dilution tunnel method for stove emissions. Adjustments to the design were made to account for flames extending up to 0.5 m above the tip of the incinerator and the drop out of large pieces of ash. Emissions were extracted into a duct for isokinetic sampling of particulate emissions. The sampling arrangement is shown by a schematic in Figure 1. A photograph of the operation over the Molope gas fired incinerator unit is shown in Figure 2.

 

All tests were performed according to specified operating procedures. The instructions provided by the supplier of the equipment were followed in the case of the C&S Marketing Unit. No operating procedures were supplied with the Molope Gas, Molope auto-combustion and PaHuOy units. These procedures were established by the CSIR personnel using their previous experience together with information provided by the supplier.

 

Test facilities were set up at the CSIR and measurements were carried out under an ISO9001 system using standard EPA test procedures or modifications made at the CSIR.

 

 

 

Figure 1. Schematic diagram of the laboratory set-up

 

 

 

 

 

Figure 2:Photograph of air intake sampling hood over Molope gas incinerator

 

 

 

5.4.   RANKING RESULTS OF THE LABORATORY TRIALS

 

Using the criteria listed under section 4.1 above, the incinerators were ranked as followed:

 

  Molope gas-fired

unit

 Molope wood-fired

unit

 C&S electric

unit

 PaHuOy wood-fired

unit
Safety 6.8 4.8 5.5 3.3
Health 5.5 3.5 4.3 2.3
Destruction 9 2 6 1
Usability 2 3 3 5
Average 5.8 3.3 4.7 2.9

 

 

5.5.   EMISSION RESULTS OF THE LABORATORY TRIALS

 

Quantitative measurements were used to rank the units in terms of destruction efficiency and the potential to produce hazardous emissions.

 

Conformance to the South African Department of Environmental Affairs and Tourism’s (DEAT) recommended guidelines on emissions from Large Scale Medical Waste Incinerators is summarized in Table 1. The measurements are listed1 in Table 2.

 

 

 

Table 1: Summary qualitative results

 

Parameter Measured Units Molope

 

Gas-fired

 Molope

 

Wood-fired

 C&S

 

Electric

 PaHuOy

 

Wood-fired

 SA DEAT

Guidelines
Stack height m × × × × 3 m above

nearest building
Gas velocity m/s × × × × 10
Residence time s × × × × 2
Minimum combustion

temperature

 ºC 4 × × × > 850
Gas combustion

efficiency

 % × × × × 99.99
Particulate emissions mg/Nm3 4 × 4 × 180
Cl as HCl mg/Nm3 × 4 4 × < 30
F as HF mg/Nm3 4 4 4 4 < 30
Metals mg/Nm3 4 × × 4 < 0.5 and

< 0.05

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

1 Emission concentrations are reported in accordance with the South African reporting requirements, ie, normalized to Normal Temperature (0

oC) and Pressure (101.3 kPa) and corrected to a nominal concentration of

8 % of CO2 on a dry gas basis. If a measurement fell below the detection limit for the method is it either reported as the detection limit or as N.D., ie, not detectable.

 

 

Table 2: Detailed quantitative results

 

 

Parameter Measured *

  

Units

  

Molope gas

  

Molope auto

  

C&S

  

PaHuOy

  

SA Process Guide1

  

Comments
 

Stack height

  

m

  

1.8

  

1.8

  

1.9

  

0.3

  

3 m above nearest building

  

None of these unite has a stack. The height of the exhaust vent is taken as the stack height. If it is above the respiration zone of the operator it provides some protection from exposure to smoke.
 

Gas velocity

  

m/s

  

0.8

  

0.5

  

1.1

  

0.5

  

10

  

Gas velocities vary across the stack for the Molope gas, Molope auto-combustion, and the PaHuOy units.
 

Residence time

  

s

  

0.4

  

0.7

  

0.6

  

0.4

  

2

  

Residence time is taken to be the total combustion time, and the maximum achievable
 

Minimum combustion zone temperature

 oC  

800 -900

  

400 – 650

  

600 – 800

  

500 – 700

  

> 850

  

Molope auto-combustion temperatures are expected to be higher as the centre of the combustion zone is not expected to be at the measurement location.
 

CO2 at the stack tip

  

% vol

  

2.64

  

3.75

  

4.9

  

3.25

  

8.0

  

Actual emission concentrations are less than the values reported here, which are normalized to 8 % CO2 and Normal temperature and pressure for reporting purposes. They are lower between 4 to 8 times.
 

Gas

  

%

  

99.91-

  

98.8 -98.4

  

99.69-

  

98.9

  

99.99

  

Most accurate measurement in
Combustion 99.70 99.03 the duct where mixing of exhaust
efficiency gases is complete. Results of two

trials.
 

Particulate emissions entrained in exhaust gas

 mg/Nm3  

102

  

197

  

130

  

338

  

180

  

The total emissions are the sum of the both entrained and un- entrained particulates. Emissions are lower than expected for such units and this is attributed to the absence of raking which is the major source of particulate emissions from incinerators without an emission control

system.
 

Particulate fall- out

 mg/Nm3  

42

  

105

  

n.d.

  

n.d.

  

  

Large pieces of paper and cardboard ash rained out of the emissions. Totalling 0.8 to 2 g over a +/- 2 minute period.
 

Soot in particulates

  

%

  

42.2

  

58.1

  

48.7

  

84.8

  

  

Correlates directly with gas combustion efficiency

 

1 Emission concentrations are reported in accordance with the South African reporting requirements, ie, Normalized to Normal Temperature (0

oC) and Pressure (101.3 kPa) and corrected to a nominal concentration of

8 % of CO2 on a dry gas basis. If a measurement fell below the detection limit for the method is it either reported as the detection limit or as N.D., ie, not detectable.

 

 

Parameter Measured *

  

Units

  

Molope gas

  

Molope auto

  

C&S

  

PaHuOy

  

SA Process Guide1

  

Comments
 

% ash residual from medical waste

  

%

  

14.8

  

12.9

  

15.6

  

21.7

  

  

Measurement of destruction efficiency of the incinerator. Typical commercial units operate at 85-90 % mass reduction. PaHuOy is lower due to the melting and unburnt plastic.
 

Cl as HCl

 mg/Nm3  

46

  

13

  

25

  

35 & 542

  

< 30

  

PaHuOy chloride concentrations varied considerably. This is expected due to the variability of the feed composition.
 

F as HF

 mg/Nm3  

< 6

  

< 1

  

<2

  

< 1

  

< 30

  

Fluoride not found in this waste.
 

Arsenic (As)

 mg/Nm3  

< 0.2

  

< 0.2

  

< 0.2

  

< 0.2

  

0.5

  

Arsenic is not expected as a solid.
 

Lead (Pb)

 mg/Nm3  

< 0.4

  

< 0.4

  

< 0.4

  

< 0.4

  

0.5

  

Lead not expected in waste
 

Cadmium (Cd)

 mg/Nm3  

< 0.2

  

< 0.2

  

< 0.2

  

< 0.2

  

0.05

  

Sensitivity of the x-ray method is adequate for ranking. Higher sensitivity not sought for this trial.
 

Chromium (Cr)

 mg/Nm3  

< 0.1

  

0.7

  

0.7

  

< 0.1.

  

0.5

  

Chromium relative to iron ranges between 12 and 25% which is consistent with stainless steel needles
 

Manganese (Mn)

 mg/Nm3  

< 0.1

  

0.3

  

0.3

  

< 0.1

  

0.5

  

Manganese may be a component in the stainless steel needle.
 

Nickel (Ni)

 mg/Nm3  

< 0.1

  

0.3

  

< 0.1

  

< 0.1

  

0.5

  

Nickel may be a component in the needle.
 

Antimony (Sb)

 mg/Nm3  

< 0.2

  

< 0.2

  

< 0.2

  

< 0.2

  

0.5

  

Not expected in this waste.
 

Barium (Ba)

 mg/Nm3  

< 0.5

  

< 0.5

  

< 0.5

  

< 0.5

  

0.5

  

Lower sensitivity due to presence in the filter material
 

Silver (Ag)

 mg/Nm3  

< 0.2

  

< 0.2

  

< 0.2

  

< 0.2

  

0.5

  

Not expected in this waste.
 

Cobalt (Co)

 mg/Nm3  

< 0.1

  

< 0.1

  

< 0.1

  

< 0.1

  

0.5

  

Cobalt might be present in stainless steel.
 

Copper (Cu)

 mg/Nm3  

< 0.5

  

< 0.5

  

< 0.5

  

< 0.5

  

0.5

  

Lower sensitivity due to copper in the sample blanks. May be background in the analytical equipment.
 

Tin (Sn)

 mg/Nm3  

< 0.2

  

< 0.2

  

< 0.2

  

< 0.2

  

0.5

  

Tin not expected in this waste.
 

Vanadium (V)

 mg/Nm3  

< 0.1

  

< 0.1

  

0.4

  

< 0.1

  

0.5

  

Vanadium might be present in stainless steel.
 

Thallium (Tl)

 mg/Nm3  

< 0.4

  

< 0.4

  

< 0.4

  

< 0.4

  

0.05

  

Not expected in this waste. Sensitivity of the x-ray method is adequate for ranking. Higher sensitivity not sought for this trial.

 

 

 

5.6.   MAIN FINDINGS OF THE LABORATORY TRIALS

 

The main conclusions drawn from the trials are as follows:

 

:::          All four units can be used to render medical waste non-infectious, and to destroy syringes or render needles unsuitable for reuse.

:::                           The largest potential health hazard arises from the emissions of smoke and soot.              (the combustion efficiency of all units lies outside the

regulatory standards). The risk to health can be reduced by training operators to avoid the smoke or by installation of a chimney at the site.

:::          The emissions from small scale incinerators are expected to be lower than those from a wood fire, but higher than a conventional fire-brick-

lined multi-chambered incinerator.

:::          Incomplete combustion, and the substantial formation of smoke at low height rendered the PaHuOy unit unacceptable for field trials. Figure 3

below shows this unit during a trial burn. Molten plastic flowed out of

the incinerator, blocked the primary combustion air feed vents, and burnt outside of the unit.

 

 

 

Figure 3: Photo of PaHuOy incinerator during trial burn

 

 

5.7.   COMPARISON OF THE FIELDS TRIALS WITH THE LABORATORY TRIALS

 

The CSIR performed a quantitative trial in the field for gas combustion efficiency, temperature profiles and mass destruction rate on the Molope Auto wood-fired unit at the Mogale Clinic.

 

The results of this trial are compared to the laboratory trial results below:

 

  • Waste loading: Disposable rubber gloves were observed in addition to needles syringes, glass vials, bandages, dressings, and paper w
  • Temperatures and combustion efficiency: The same performance in gas combustion        efficiency   was    obtained    for    wood    .

Temperatures were higher but for a shorter time and this was

correlated with the type of wood available to the clinic. The fuel was burnt out before the medical waste was destroyed completely and this resulted in lower temperatures, lower combustion efficiency and higher emissions while burning the waste.

  • Emissions: Large amounts of black smoke were observed and this was correlated directly to cooling of the unit as the wood fuel was exhausted

prior to full ignition of the waste.

  • Destruction efficiency: The destruction efficiency was similar to that in the laboratory measurem
  • Usability: The unit is difficult to control as the result of the variability of the quality of wood
  • Acceptability: the smoke was not acceptable to the clinic, the community, or the local

 

It was concluded that:

  • The performance with fuel alone indicates that laboratory trial data can be used to predict emissions in the
  • The Molope Auto unit is too difficult to control for the available staff and fuel at the

 

 

 

5.8.   RECOMMENDATIONS FROM THE LABORATORY TRIALS

 

The following recommendations are made as the result of the laboratory trials:

:::     A comprehensive operating manual must be supplied with each unit.

Adequate training in the operation of the units must be provided, especially focussed on safety issues.

:::     It is recommended that the height of the exhaust vent on all units be

addressed.     In order to facilitate the dispersion of emissions and reduce the exposure risk of the operators.

:::     The suppliers of the incinerators must provide instructions for the safe handling and disposal of ash.

 

 

 

5.9.   RECOMMENDATIONS FROM THE STEERING COMMITTEE

 

 

 

After completion of the laboratory trials, the project steering committee recommended that the Molope Gas and C&S Marketing units be submitted for field testing. The Molope Auto was recommended for field testing on the condition that the manufacturer modified the ash grate so as to prevent the spillage of partially burnt needles and syringes.

 

 

 

6.     FIELD TRIALS

 

6.1.   OBJECTIVE OF THE FIELD TRIALS

 

The objective of the field trials was to obtain information in the field and assess the strengths and weaknesses of each of the incinerators during use at primary health care clinics.

 

A participative decision making process was used for the trials. It was based on expert technical evaluation by the CSIR and the National Department of Health as well as participation in the trials by experienced end users and participating advisors. All decisions were made by the Steering Committee, which consisted of representatives of stakeholders in the clinical and medical waste disposal process. These included representatives from the National, Provincial, and Local Government departments of Health, Safety and the Environment, as well as Professional Associations, Unions, NGOs, UNICEF, the WHO and local community representatives.

 

6.2.   CLINIC SELECTION

 

The Provinces in which the trials were done selected clinics for the field trials. The criteria set by the Steering Committee for the selection of the clinics were the following:

 

  • Location must be rural or under-serviced with

y No medical waste removal

y No existing incineration

y No transport

  • It must be in a high-density population area
  • Acceptable environmental conditions must prevail
  • Community acceptance must be obtained
  • Operator skill level to be used must be at a level of illiteracy

 

The clinics that were selected were as follows:

 

  • Steinkopf Clinic – Northern Cape Province – Gas incinerator

 

 

  • Marydale Clinic – Northern Cape Province – Gas incinerator
  • Mogale Clinic – Gauteng Province             – Auto combustion

incinerator, wood-fired.

  • Chwezi Clinic – KwaZulu-Natal Province – Gas incinerator
  • Ethembeni Clinic- KwaZulu-Natal Province – Auto-combustion electrical

incinerator

 

 

 

 

 

 

MAP OF SOUTH AFRICA INDICATING WHERE THE CLINICS ARE SITUATED

 

 

 

 

 

 

 

 

NORTHERN PROVINCE

 

GAUTENG PROVINCE

 

 

 

 

 

NORTH WEST PROVINCE

MPUMALANGA PROVINCE

 

 

 

 

 

 

FREE STATE PROVINCE

 

 

NORTHERN CAPE PROVINCE

 

 

KWAZULU-NATAL PROVINCE

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

I:/UnitPublic/Valerie/Technet 99/Working papers/Session 3/rogers.doc

 

 

 

EASTERN CAPE PROVINCE

 

 

WESTERN CAPE PROVINCE

 

 

6.3.   COORDINATION OF THE TRIALS

 

The criteria for the ranking of the incinerators in accordance with performance in the field were:

 

  • Safety (occupational and public health)
  • Destruction capability
  • Usability
  • Community acceptability

 

The South African National Department of Health coordinated the field trials.

 

Information regarding the field trials as well as questionnaires were supplied to the coordinators in the participating provinces.

 

The team in the field consisted of the operator, supervisor and inspector (coordinator). The manufacturer of the incinerators did the training of the operators.

 

The questionnaires used during the trials were set so as to obtain information with regard to the criteria set for the ranking of the incinerators in accordance with performance in the field. The questionnaires were received from the clinics at two-weekly intervals.

 

Questions with regard to the criteria were the following:

 

A.  SAFETY (occupational and public health)

 

  • Smoke Emission

y Volume and thickness

y Colour

y Odour

  • Ash Content
  • Are the filled sharps boxes and soiled dressings stored in a locked location while waiting to be incinerated?

 

 

 

B.  DESTRUCTION CAPABILITY

 

  • Destruction Rate

y Complete

y Partial

y Minimal

y Residue content

 

C.  USABILITY (for the available staff)

  • Can the incinerator be used easily?

 

 

  • Is the process of incineration safe?
  • Has training been successful?
  • Is protective clothing such as gloves, goggles, dust masks and safety boots available?

 

D.  COMMUNITY ACCEPTABILITY

 

  • What is the opinion of the following persons on the use of the incinerator?

y Operator

y Nurse

y Head of the clinic

y Local Authority representative

y Community leader

 

During the trials the clinics were visited and the incinerators evaluated by members of the Steering Committee and the CSIR as well as Dr L Diaz from WHO, Mr M Lainejoki from UNICEF and the coordinator from the National Department of Health.

 

6.4.   QUESTIONNAIRE RESULTS

 

6.4.1.      MOGALE CLINIC

 

Type of incinerator at the clinic: Molope Auto-Combustion (Fired with wood)

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 4 & 5: Molope Auto wood-fired incinerator during field trials at Mogale clinic

 

 

A.               SAFETY (occupational and public health)

 

  1. The process of incineration with this unit was considered by the operator, supervisor and the inspector as unsafe because there is no protective cage around the During the process the incinerator becomes very hot and this could result in injury to the operator.

 

  1. The smoke emission of this incinerator had a volume and thickness which was heavy and black, with a distinct unpleasant odour, and was considered This could cause a pollution problem.

 

 

 

B.               DESTRUCTION CAPABILITY

 

  1. The needles and vials were not completely destroyed but were rendered unsuitable for re-use.

 

  1. The soft medical waste was completely destroy

 

 

 

C.               USABILITY

 

Difficulty in controlling the operating temperature and avoiding smoke emissions made this incinerator user unfriendly.

 

D.               COMMUNITY ACCEPTABILITY

 

As a result of the heavy, black smoke emission the unit was not acceptable to the community.

 

 

6.4.2.      ETHEMBENI CLINIC:

 

 

Figure 6: C&S Marketing Auto Combust Electrical Incinerator At Ethembeni Clinic

 

 

 

Type Of Incinerator: C&S Auto-Combustion (Uses an electrically actuated fan)

 

 

 

A.               SAFETY (occupational and public health)

 

  1. The operator, supervisor and inspector considered this incinerator easy to operate with no danger to the Removal of the ash from the drum for disposal in a pit is, however, considered difficult, as the drum is heavy. Removal of the incinerator lid before it has been allowed to cool has been identified as a potential danger to the operator.

 

  1. Emission of smoke from this incinerator was not considered ex The volume and thickness was evaluated as moderate with no pollution experienced.

 

 

 

B.               DESTRUCTION CAPABILITY

 

  1. The needles and vials were not completely destroyed but were rendered unsuitable for re-use.
  2. The soft medical waste was completely destroy

 

 

 

C.               USABILITY

 

Considered user friendly by operator, supervisor and inspector.

 

D.               COMMUNITY ACCEPTABILITY

 

The incinerator was accepted by the community and was not considered to be harmful.

 

 

 

6.4.3.      CHWEZI CLINIC, MARYDALE CLINIC AND STEINKOPF CLINIC:

 

Type of incinerator: Molope Gas incinerator

 

Figure 7:       Molope Gas incinerator during field trials at Marydale clinic

 

A.               SAFETY (occupational and public health)

 

  1. The operator, supervisor and inspector considered this incinerator easy to operate with minimal danger to the
  2. Smoke emissions were not excessive and were reported to be minim

 

B.               DESTRUCTION CAPABILITY

 

  1. Sharps not completely destroyed but were rendered unsuitable for re-use.

 

 

  1. Soft medical waste completely destroy

 

C.               USABILITY

 

This incinerator was considered user friendly.

 

 

 

D.               COMMUNITY ACCEPTABILITY

 

 

 

The incinerator was accepted by the community and was not considered to be harmful.

 

 

 

6.5.   RANKING

 

 

INCINERATOR RANKING
Molope Gas 1
C&S Auto-Combustion (Uses electrical fan)  

2
Molope Auto- Combustion (Fired with

wood, coal also an option)

  

3

 

 

 

 

6.6.   OUTCOME OF THE FIELD TRIALS

 

Incinerator Safety Destruction Capability Usability Community Acceptability
Molope Gas Good Good Good Good
C&S Auto- Combustion

(Uses Electricity)

  

Good

  

Good

  

Good

  

Good
Molope Auto-

Combust Incinerator

 Un-Acceptable Good Un-Acceptable Un-Acceptable