Calculating The Heat Demand For Dhw Heating In Commercial Enterprises; Calculating The Heat Demand For Dhw Heating In Hotels, Guest Houses And Residential Homes - Viessmann Vitocell 300-H Technical Manual

Sizing
(cont.)

Calculating the heat demand for DHW heating in commercial enterprises

1. Demand calculation
Allow for a suitable number of washing facilities (washing/shower
units) for the type of business concerned (see the earlier DIN 18228,
part 3, page 4).
Per 100 users (numbers in the most numerous shift), the washing
facilities listed in table 7 are required.
Table 7 – Standard working conditions
Activity Number of washing
facilities per 100
users
Slightly dirty
Moderately dirty
Very dirty
2. Sizing the DHW heating system
The following example is used to illustrate how to size the DHW
heating system.
Example:
Number of employees during the most numerous
shift:
Working pattern:
Type of activity:
Required DHW outlet temperature:
Cylinder storage temperature:
4
Cold water inlet temperature:
Heating water flow temperature:
Calculating the DHW demand
Table 7 shows that for moderately dirty work, 20 washing facilities
are required per 100 employees. The ratio of washbasins to shower
units is 2:1.
Therefore, 20 washbasins and 10 shower units are required for 150
employees.
Table 8 – Consumption figures for washing facilities and
shower units with a DHW outlet temperature of 35 to 37 °C
Consumption point
Washbasins with tap
Washbasins with spray
head
Circular communal wash-
basin for 6 people
Circular communal wash-
basin for 10 people
Shower unit without
changing cubicle
Shower unit with chang-
ing cubicle
Assumptions:
The washing facilities (washbasin with spray head) are used by 120
employees (6 times in sequence) and the shower units (showers
without changing cubicles) are used by 30 employees (3 times in
sequence).

Calculating the heat demand for DHW heating in hotels, guest houses and residential homes

To calculate the DHW demand, it is necessary to establish the points
of use in every room.
*9 In businesses with exceptionally dirty working conditions, 25 washing facilities are required per 100 users.
*10 Showering time excluding changing.
*11 Showering time 5 to 8 min; rest of time for changing.
VIESMANN
18
*9
Splitting the washing fa-
cilities
Washing facilities/shower
units
15
20
25
150 employees
2-shift operation
Moderately dirty
35 to 37 °C
60 °C
10 °C
90 °C
DHW vol- Utilisation DHW con-
ume in time in min sumption
l/min per use in
l
5 to 12 3 to 5
3 to 6 3 to 5
approx. 20 3 to 5
approx. 25 3 to 5
7 to 12 *10
5 to 6
7 to 12 *11
10 to 15
Using table 8, we arrive at the following DHW volume required:
a) DHW demand of the washing facilities: 120 × 3.5 l/min × 3.5 min
= 1470 l
b) DHW demand of the showers: 30 × 10 l/min × 5 min = 1500 l
Together, a) and b) result in a total DHW demand of 2970 l at
approx. 36 °C water temperature for a utilisation period of approx. 25
minutes.
Conversion to an outlet temperature of 45 °C results in:
ΔT
(36°C – 10°C)
V = V ·
(45°C) (36°C)
ΔT
(45°C – 10°C)
26
= 2970 · =2206 l
–/–
35
2/1
1/1
As 8 hours are available between the shifts for reheating the DHW
cylinder, the cylinder capacity should be sized for storage purposes.
For this, the details for the peak output (10-minute peak output) in
the tables in the relevant datasheets for the DHW cylinders are
used.
From the corresponding table in the Vitocell 300-V datasheet: For
Vitocell 300-V with 500 l capacity and a heating water flow tempera-
ture = 90 °C, the peak output is 10/45 °C 634 l/10 min.
Number of DHW cylinders n = calculated total volume/selected peak
output (10 min output) of the individual cylinder
2206
n = = 3.5 pce
634
Selected DHW cylinder:
4 × Vitocell 300-V, each with 500 l capacity.
Calculating the required heating output
7.5 hours are available for heating up the DHW cylinder; this gives a
minimum connected load (i.e. boiler heating output) of:
c · V · ΔT
A
= Φ =
²
A A
Z
A
1 · 2000 · 50
=
860 · 7.5
= Minimum connected load for heating the DHW cyl-
or Φ
²
30 A A
inder in kW
15
V = Selected cylinder capacity in l
c = Spec. thermal capacity
75
1 kWh
860 l · K
75
ΔT = Temperature differential between the cylinder stor-
A
age temperature and the cold water inlet tempera-
50
ture
(60 °C – 10 °C) = 50 K
80
Z = Heat-up time in h
A
As an empirical value, a heat-up time of approx. 2 hours is selected.
In the above example, this means that the boiler and the circulation
pump for cylinder heating (required heating water volume) should be
sized for a heat-up rating of approx. 60 kW.
For this, only consider the largest point of use per single/double
room.
= 15.5 kW
DHW heating