Article Type: Research Article Article Citation: Stanley Emmanuel Ubi,
Paul Nkra Obun, Agbor Reagan B, Thankgod Tom, and
Monday Agbor. (2020). EFFECT OF DAMP AND TREATMENT
METHODS ON RESIDENTIAL BUILDINGS IN CALABAR METROPOLIS OF CROSS RIVER STATE. International
Journal of Research -GRANTHAALAYAH, 8(8), 372-376. https://doi.org/10.29121/granthaalayah.v8.i8.2020.1206 Received Date: 18 August 2020 Accepted Date: 31 August 2020 Keywords: Damp Treatment Residential Buildings The main purpose of this study was to investigate the effect of damp and treatment methods on residential buildings in Calabar Metropolis of Cross River State. Damp is a pervasive problem for residential buildings. It is at times expressed in the most unlikely places under unexpected and unsettling conditions due to heavy rainfall. It is usually expressed at home, market, and neighborhood or within community. At different-occasions damp had cause many damages to school properties, destruction of roads especially during rainy season. To achieve the purpose of this study two research questions were formulated to direct the study. Survey research design was adopted for the study. A sample of one hundred respondents was randomly selected for the study. The selection was done through the simple random sampling technique. This was to give equal and independent opportunities to all the respondents to be selected for the study. The questionnaire was the instrument used for data collection. The instrument was subjected to face validation by experts in measurement and evaluation. The reliability estimate of the instrument was established through the test re-test reliability method. The results of the respondents reveal that damp and treatment method significantly influence residential buildings in Calabar Metropolis. Based on the findings, it was recommended among others that the State government should construct good drainage system to enhance the free flow of stagnant water during or after rainfall in order not to cause damages to the buildings.
1. INTRODUCTIONDamp is a pervasive problem for Calabar Metropolis. Most at
times it occurred unexpectedly when there is heavy down-pour. Dampness is the presence
of unwanted moisture in the structure of a residential or commercial building,
it occurs mainly in old buildings, either the result of water over running from
outside or condensation from within the structure. Moisture in buildings is a
major contributor to mold growth, unhealthy buildings, and poor indoor air
quality. A high proportion of damp problems in buildings are
caused by ambient climate dependent factors of condensation and rain
penetration (Prowler
2011). Dampness in buildings can damage much more than a
buildings appearance. It may lead to deterioration of plaster and masonry,
promote timber decay and create unhealthy condensation (Oliver 2017). Dampness
tends to cause secondary damage to a building. The unwanted moisture enables
the growth of various fungi in wood, causing rot or mold
health issues, could eventually lead to sick building syndrome.
Molds can grow on almost any surface and occur where there is a lot of moisture
from structural problems such as leaky roofs or high humidity levels. One of
the most important requirements of a building is that it should remain dry,
that is, damp proof. In the event that this condition is not fulfilled, all
things considered, the structure may get unhygienic to the occupants and
dangerous from the structural perspective, since dampness breeds germs of
specific illnesses and deteriorates the structure. Damp in building can occur
naturally when the foundation of a building is not well treated with the
appropriate material which may lead to rising damp. Burkinshaw
and Parrett (2004), explained that a building can be described as having a
dampness effect or problem when the materials contained in that building
becomes sufficiently damp to cause material damage and visible mold growth. Hall
et al., (2011), noted that damages to structures brought about by
dampness represent a genuine risk to the performance of the structure and
infiltration of dampness/moisture through the fabric of structures over some
undefined time frame and is typically described by localized regions of damp or
immersed wall/ceiling finishes. Alfano etal.
(2006), ascertained that damp in building can be caused by bad
eaves or inadequate gutters or cracked roofing tiles, broken pointing, improper
wall thickness, poor construction and inadequate protection. However, when
considering the causes of damp we should know that
damp occur in different means which are condensation, rain penetration, rising
damp and humidity. Beal (2000),
consider the concurrent event of the presence of water, an opening through
which water can enter and a physical power to move the water are the three
primary issues that support water infiltration through a structure enclosure.
Ralf (2008), describes damp as a level on the external envelop of a building
which are liable to moisture effects caused by pooling or splashing or
impinging of (usually) rain water at the junction of a horizontal surface to
the vertical wall surface-being most common at the wall base. In line with the above, Broady (2019), opines that condensation is
caused when the vapour of water inside a structure
can move outward by means of diffusion through permeable structure fabric or
air development and arrive at a surface inside the structure cavity that is
underneath the dew point. That surface might be smooth, for example, sheet
metal, or fibrous, for example, glass wool insulation. A cold surface that
gathers vapour assimilates the warmth of
vaporization, raising its temperature marginally. In this manner condensation
can be generally quick on a metal frame, and less fast on an insulation
material. Be that as it may, given time, both may condense a considerable
amount of water. Interstitial
condensation can be definitely more harming to the structure than surface condensation.
Interstitial condensation can go unnoticed and if the structure fabric has not
been intended to enable dampness to dry from inside, it can get caught and
compromise the strength/durability of the structure and the wellbeing of the
inhabitants. However, building with poorly insulated walls is very prone to
this problem. It regularly causes harms like damp in a structure and frequently
shows up in comparative spots. Damp gathers on the inside of the structures
because of explicit communications between the rooftop and walls. In Cross River State, damp has been a
major issue which affects buildings. Damp has put the life of occupant, at risk
and causing health problems such as asthma, it causes damage to their
properties and also the deterioration of building. However, the problem of damp
in the buildings occur when there is a lot of moisture in the structure, such
as leaky roofs or high humidity levels whereby mortar or plaster may fall away
from the affected wall, causing a poor indoor air quality and respiratory
illness in occupants. Hence there is need to find out the causes, prevention
and treatment of damp in buildings. 2. MATERIALS AND METHODS
The research design used for this study was Survey research
design, through the use of observation with the aid of checklist and visual
inspection. This was carried out in order to describe the observable fact or
occurrence the way they are manifested in natural settings and buildings. The
population of this study comprises of all the Landlord/Landladies in Calabar
Metropolis of Cross River State of Nigeria. The sampling technique adopted for
this study was the simple random sampling technique. One hundred (100)
individuals were randomly selected from five communities in Calabar Metropolis.
The main instrument used for data collection was the research questions
designed by the researcher through the assistant of experts. The items in the
research questions were drawn in reflection of the variables under study.
Before using the instrument the items developed were
given to experts in research and statistics for screening. To determine the
reliability of the instrument, a trial testing was done using twenty (20)
respondents. Test re-test reliability method was used to determine the
reliability coefficient of the instrument. 3. RESULTS AND DISCUSSIONThe variables were identified and statistical analysis carried out to provide answers to the research questions. The 0.05 level of significance was used for the statistical testing of each research question. 3.1. RESEARCH QUESTION ONETo what extent does damp affect residential buildings? To provide answer for this research question, data were gathered and analyzed as presented in Table 1. Table 1: Responses of respondent of whether
damp affect residential buildings in Calabar Metropolis of Cross River State.
The Table 1 above reveals that all the itemized columns are the causes of damp in the Calabar Metropolis of Cross River State. It further indicated that 14 representing (70%) of respondents agreed that rain penetration affect residential building; while 6 representing (30%) of respondents do not. Again, 18 representing (90%) of respondents agreed that rising damp affect residential building; while 2 representing (10%) of respondents do not. Also, 10 representing (50%) of respondents agreed that condensation affect residential building; while 10 representing (50%) of respondents do not. More so, 12 representing (60%) of respondents agreed that roof leakages significantly affect residential building; while 8 representing (40%) of respondents do not. Finally, 14 representing (70%) of respondents agreed that drainage affect residential building; while 6 representing (30%) of respondents do not. 3.2. RESEARCH QUESTION TWOHow does treatment method impact to residential buildings? The data were gathered and analyzed in order to provide answer for the research question 2 as presented in Table 2. Table 2: Responses of
respondent of whether treatment method has any impact on residential buildings
in Calabar Metropolis of Cross River State.
In accordance to the above Table 2, it is clearly stated that all the itemized columns are the measure for treatment method in the Calabar Metropolis of Cross River State. However, based on individual responses, it was denoted that, 13 representing (65%) of respondents agreed that treatment of foundations against gravitational water has significant impact on residential building; while 7 representing (35%) of respondents do not. Again, 16 representing (80%) of respondents agreed that treatment of basements has significant impact on residential buildings; while 4 representing (20%) of respondents do not. Also, 12 representing (60%) of respondents agreed that there is significant impact of floors treatment on residential buildings; while 8 representing (40%) of respondents do not. Furthermore, 18 representing (90%) of respondents agreed that treatment of walls has significant impact on residential buildings; while 2 representing (10%) of respondents do not. Conclusively, 11 representing (55%) of respondents agreed that treatment of flat roofs has great implication on residential buildings; while 9 representing (45%) of respondents do not. 4. DISCUSSION OF FINDINGSFrom the research paper it shows that the causes of dampness are link to factors such as rain penetration, rising damp, condensation, humidity, roof leakage and lack of drainage and this factors significantly affect residential buildings in Calabar Metropolis. In agreement to the finding, Alfano, et al., (2006) opined that rain penetration from the wall can be treated by providing adequate wall thickness or cavity walls, exposed wall faces should be of good quality and have a low water absorption capacity and covered with cement plaster. Similarly, Hutton (2011) asserted that condensation can be treated by increasing background heat, ventilation of cold surfaces, reducing moisture generation. In another finding, it revealed that treatment method has a significant impact on residential buildings among Calabar Metropolis dwellers. In line to the BMJ (1872), rising damp can be treated by replacement of physical damp-roof course, Injection of a liquid or cream chemical damp proof course (DPC Injection), Damp-proofing rods, Porous tubes/other evaporative, land drainage, electro-osmotic system and plastering. Godish (2001), also observed that roof leakages can be prevented when we pay attention to roof flashings. Without great, tight flashings around chimneys, vents, skylight, and wall or rooftop intersection, water can enter a home and cause harm to walls, ceiling, insulation and electrical framework. Hence, without legitimate ventilation, warmth and moisture develop can cause rafters and sheathing decay, shingles to buckle, and protection to lose its viability. Never block wellsprings of ventilation, for example, louvers, ridge vents or soffit vents. Legitimate air ventilation will help forestall auxiliary harm brought about by dampness and mold, increment roofing material life. Perry and Green (2007), also opined strategies to prevent humidity in structure is to make sure an activity as simple as cooking dinner, taking a shower, or doing a load of laundry doesn't invite mold by providing proper ventilation in your bathroom, kitchen, laundry room, and any other high-moisture area. So open the window when cooking or washing dishes or showering, or run an exhaust fan. 5. CONCLUSIONSDampness is a major contributing factor to building defection and it impact negatively on residential building, thereby reducing the life-span of the building and endanger the life of occupants. Based on visual inspection and interview carried out, the data showed that dampness exists in landed residential buildings. From this research paper it could be denoted that, factors like faulty construction method, poor construction materials, lack of maintenance and poor drainage system should be avoided, beginning from the pre-construction, during construction and post construction stage by the professionals involved to avoid dampness or any building defect. Problem associated with various forms of dampness and the necessary measures of treatment needed to pro-long the life span of a building were also disclosed. SOURCES OF FUNDINGThis research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors. CONFLICT OF INTERESTThe author have declared that no competing interests exist. ACKNOWLEDGMENTNone. REFERENCES
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